Your search keyword '"DNA Replication genetics"' showing total 400 results

1. High fidelity DNA ligation prevents single base insertions in the yeast genome.

Author

Williams JS, Lujan SA, Arana ME, Burkholder AB, Tumbale PP, Williams RS, and Kunkel TA

Subjects

Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, DNA genetics, DNA metabolism, Mutagenesis, Insertional, Mutation, DNA Ligases metabolism, DNA Ligases genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, DNA Mismatch Repair genetics, DNA Ligase ATP genetics, DNA Ligase ATP metabolism, Genome, Fungal, DNA, Fungal genetics, DNA, Fungal metabolism, DNA Replication genetics

Abstract

Finalization of eukaryotic nuclear DNA replication relies on DNA ligase 1 (LIG1) to seal DNA nicks generated during Okazaki Fragment Maturation (OFM). Using a mutational reporter in Saccharomyces cerevisiae, we previously showed that mutation of the high-fidelity magnesium binding site of LIG1 Cdc9 strongly increases the rate of single-base insertions. Here we show that this rate is increased across the nuclear genome, that it is synergistically increased by concomitant loss of DNA mismatch repair (MMR), and that the additions occur in highly specific sequence contexts. These discoveries are all consistent with incorporation of an extra base into the nascent lagging DNA strand that can be corrected by MMR following mutagenic ligation by the Cdc9-EEAA variant. There is a strong preference for insertion of either dGTP or dTTP into 3-5 base pair mononucleotide sequences with stringent flanking nucleotide requirements. The results reveal unique LIG1 Cdc9 -dependent mutational motifs where high fidelity DNA ligation of a subset of OFs is critical for preventing mutagenesis across the genome., (© 2024. This is a U.S. Government work and not under copyright protection in the US; foreign copyright protection may apply.)

Published

2024

2. The budding yeast Fkh1 Forkhead associated (FHA) domain promotes a G1-chromatin state and the activity of chromosomal DNA replication origins.

Author

Hoggard T, Chacin E, Hollatz AJ, Kurat CF, and Fox CA

Subjects

Forkhead Transcription Factors genetics, Forkhead Transcription Factors metabolism, S Phase genetics, Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, Protein Domains genetics, Binding Sites, Protein Binding, Chromosomes, Fungal genetics, Chromosomes, Fungal metabolism, Nucleosomes metabolism, Nucleosomes genetics, Replication Origin genetics, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, DNA Replication genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Chromatin genetics, Chromatin metabolism, Origin Recognition Complex genetics, Origin Recognition Complex metabolism, G1 Phase genetics

Abstract

In Saccharomyces cerevisiae, the forkhead (Fkh) transcription factor Fkh1 (forkhead homolog) enhances the activity of many DNA replication origins that act in early S-phase (early origins). Current models posit that Fkh1 acts directly to promote these origins' activity by binding to origin-adjacent Fkh1 binding sites (FKH sites). However, the post-DNA binding functions that Fkh1 uses to promote early origin activity are poorly understood. Fkh1 contains a conserved FHA (forkhead associated) domain, a protein-binding module with specificity for phosphothreonine (pT)-containing partner proteins. At a small subset of yeast origins, the Fkh1-FHA domain enhances the ORC (origin recognition complex)-origin binding step, the G1-phase event that initiates the origin cycle. However, the importance of the Fkh1-FHA domain to either chromosomal replication or ORC-origin interactions at genome scale is unclear. Here, S-phase SortSeq experiments were used to compare genome replication in proliferating FKH1 and fkh1-R80A mutant cells. The Fkh1-FHA domain promoted the activity of ≈ 100 origins that act in early to mid- S-phase, including the majority of centromere-associated origins, while simultaneously inhibiting ≈ 100 late origins. Thus, in the absence of a functional Fkh1-FHA domain, the temporal landscape of the yeast genome was flattened. Origins are associated with a positioned nucleosome array that frames a nucleosome depleted region (NDR) over the origin, and ORC-origin binding is necessary but not sufficient for this chromatin organization. To ask whether the Fkh1-FHA domain had an impact on this chromatin architecture at origins, ORC ChIPSeq data generated from proliferating cells and MNaseSeq data generated from G1-arrested and proliferating cell populations were assessed. Origin groups that were differentially regulated by the Fkh1-FHA domain were characterized by distinct effects of this domain on ORC-origin binding and G1-phase chromatin. Thus, the Fkh1-FHA domain controlled the distinct chromatin architecture at early origins in G1-phase and regulated origin activity in S-phase., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 Hoggard et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

3. rDNA transcription, replication and stability in Saccharomyces cerevisiae.

Author

D'Alfonso A, Micheli G, and Camilloni G

Subjects

Humans, DNA, Ribosomal genetics, DNA, Ribosomal metabolism, Genomic Instability genetics, DNA Replication genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism

Abstract

The ribosomal DNA locus (rDNA) is central for the functioning of cells because it encodes ribosomal RNAs, key components of ribosomes, and also because of its links to fundamental metabolic processes, with significant impact on genome integrity and aging. The repetitive nature of the rDNA gene units forces the locus to maintain sequence homogeneity through recombination processes that are closely related to genomic stability. The co-presence of basic DNA transactions, such as replication, transcription by major RNA polymerases, and recombination, in a defined and restricted area of the genome is of particular relevance as it affects the stability of the rDNA locus by both direct and indirect mechanisms. This condition is well exemplified by the rDNA of Saccharomyces cerevisiae. In this review we summarize essential knowledge on how the complexity and overlap of different processes contribute to the control of rDNA and genomic stability in this model organism., Competing Interests: Declaration of Competing Interest none., (Copyright © 2024 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2024

4. Physical interactions between specifically regulated subpopulations of the MCM and RNR complexes prevent genetic instability.

Author

Yáñez-Vilches A, Romero AM, Barrientos-Moreno M, Cruz E, González-Prieto R, Sharma S, Vertegaal ACO, and Prado F

Subjects

Protein Serine-Threonine Kinases genetics, Protein Serine-Threonine Kinases metabolism, DNA Helicases genetics, DNA Helicases metabolism, Minichromosome Maintenance Proteins metabolism, Minichromosome Maintenance Proteins genetics, Replication Protein A metabolism, Replication Protein A genetics, Ribonucleoside Diphosphate Reductase genetics, Ribonucleoside Diphosphate Reductase metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, DNA Replication genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, DNA Damage genetics, Cell Cycle Proteins metabolism, Cell Cycle Proteins genetics, Rad52 DNA Repair and Recombination Protein metabolism, Rad52 DNA Repair and Recombination Protein genetics, Genomic Instability, Ribonucleotide Reductases genetics, Ribonucleotide Reductases metabolism, DNA Repair genetics

Abstract

The helicase MCM and the ribonucleotide reductase RNR are the complexes that provide the substrates (ssDNA templates and dNTPs, respectively) for DNA replication. Here, we demonstrate that MCM interacts physically with RNR and some of its regulators, including the kinase Dun1. These physical interactions encompass small subpopulations of MCM and RNR, are independent of the major subcellular locations of these two complexes, augment in response to DNA damage and, in the case of the Rnr2 and Rnr4 subunits of RNR, depend on Dun1. Partial disruption of the MCM/RNR interactions impairs the release of Rad52 -but not RPA-from the DNA repair centers despite the lesions are repaired, a phenotype that is associated with hypermutagenesis but not with alterations in the levels of dNTPs. These results suggest that a specifically regulated pool of MCM and RNR complexes plays non-canonical roles in genetic stability preventing persistent Rad52 centers and hypermutagenesis., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 Yáñez-Vilches et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

5. Defective transfer of parental histone decreases frequency of homologous recombination by increasing free histone pools in budding yeast.

Author

Karri S, Yang Y, Zhou J, Dickinson Q, Jia J, Huang Y, Wang Z, Gan H, and Yu C

Subjects

Mutation, Chromatin metabolism, Chromatin genetics, DNA Polymerase II metabolism, DNA Polymerase II genetics, Epigenesis, Genetic, DNA Repair, Histones metabolism, Histones genetics, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Homologous Recombination genetics, DNA Replication genetics

Abstract

Recycling of parental histones is an important step in epigenetic inheritance. During DNA replication, DNA polymerase epsilon subunit DPB3/DPB4 and DNA replication helicase subunit MCM2 are involved in the transfer of parental histones to the leading and lagging strands, respectively. Single Dpb3 deletion (dpb3Δ) or Mcm2 mutation (mcm2-3A), which each disrupts one parental histone transfer pathway, leads to the other's predominance. However, the biological impact of the two histone transfer pathways on chromatin structure and DNA repair remains elusive. In this study, we used budding yeast Saccharomyces cerevisiae to determine the genetic and epigenetic outcomes from disruption of parental histone H3-H4 tetramer transfer. We found that a dpb3Δ mcm2-3A double mutant did not exhibit the asymmetric parental histone patterns caused by a single dpb3Δ or mcm2-3A mutation, suggesting that the processes by which parental histones are transferred to the leading and lagging strands are independent. Surprisingly, the frequency of homologous recombination was significantly lower in dpb3Δ, mcm2-3A and dpb3Δ mcm2-3A mutants, likely due to the elevated levels of free histones detected in the mutant cells. Together, these findings indicate that proper transfer of parental histones during DNA replication is essential for maintaining chromatin structure and that lower homologous recombination activity due to parental histone transfer defects is detrimental to cells., (© The Author(s) 2024. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2024

6. Parental histone transfer caught at the replication fork.

Author

Li N, Gao Y, Zhang Y, Yu D, Lin J, Feng J, Li J, Xu Z, Zhang Y, Dang S, Zhou K, Liu Y, Li XD, Tye BK, Li Q, Gao N, and Zhai Y

Subjects

Binding Sites, Cryoelectron Microscopy, DNA, Fungal biosynthesis, DNA, Fungal chemistry, DNA, Fungal metabolism, DNA, Fungal ultrastructure, Multienzyme Complexes chemistry, Multienzyme Complexes metabolism, Multienzyme Complexes ultrastructure, Nucleosomes chemistry, Nucleosomes metabolism, Nucleosomes ultrastructure, Protein Binding, Protein Domains, Protein Multimerization, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins metabolism, Saccharomyces cerevisiae Proteins ultrastructure, Chromatin chemistry, Chromatin genetics, Chromatin metabolism, Chromatin ultrastructure, DNA Replication genetics, Epistasis, Genetic genetics, Histones chemistry, Histones metabolism, Histones ultrastructure, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae ultrastructure

Abstract

In eukaryotes, DNA compacts into chromatin through nucleosomes 1,2 . Replication of the eukaryotic genome must be coupled to the transmission of the epigenome encoded in the chromatin 3,4 . Here we report cryo-electron microscopy structures of yeast (Saccharomyces cerevisiae) replisomes associated with the FACT (facilitates chromatin transactions) complex (comprising Spt16 and Pob3) and an evicted histone hexamer. In these structures, FACT is positioned at the front end of the replisome by engaging with the parental DNA duplex to capture the histones through the middle domain and the acidic carboxyl-terminal domain of Spt16. The H2A-H2B dimer chaperoned by the carboxyl-terminal domain of Spt16 is stably tethered to the H3-H4 tetramer, while the vacant H2A-H2B site is occupied by the histone-binding domain of Mcm2. The Mcm2 histone-binding domain wraps around the DNA-binding surface of one H3-H4 dimer and extends across the tetramerization interface of the H3-H4 tetramer to the binding site of Spt16 middle domain before becoming disordered. This arrangement leaves the remaining DNA-binding surface of the other H3-H4 dimer exposed to additional interactions for further processing. The Mcm2 histone-binding domain and its downstream linker region are nested on top of Tof1, relocating the parental histones to the replisome front for transfer to the newly synthesized lagging-strand DNA. Our findings offer crucial structural insights into the mechanism of replication-coupled histone recycling for maintaining epigenetic inheritance., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

7. The Saccharomyces cerevisiae mitochondrial DNA polymerase and its contribution to the knowledge about human POLG-related disorders.

Author

Gilea AI, Magistrati M, Notaroberto I, Tiso N, Dallabona C, and Baruffini E

Subjects

Animals, Humans, DNA Polymerase gamma genetics, DNA Polymerase I genetics, DNA Polymerase I metabolism, DNA, Mitochondrial genetics, Mutation, DNA Replication genetics, Saccharomyces cerevisiae, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism

Abstract

Most eukaryotes possess a mitochondrial genome, called mtDNA. In animals and fungi, the replication of mtDNA is entrusted by the DNA polymerase γ, or Pol γ. The yeast Pol γ is composed only of a catalytic subunit encoded by MIP1. In humans, Pol γ is a heterotrimer composed of a catalytic subunit homolog to Mip1, encoded by POLG, and two accessory subunits. In the last 25 years, more than 300 pathological mutations in POLG have been identified as the cause of several mitochondrial diseases, called POLG-related disorders, which are characterized by multiple mtDNA deletions and/or depletion in affected tissues. In this review, at first, we summarize the biochemical properties of yeast Mip1, and how mutations, especially those introduced recently in the N-terminal and C-terminal regions of the enzyme, affect the in vitro activity of the enzyme and the in vivo phenotype connected to the mtDNA stability and to the mtDNA extended and point mutability. Then, we focus on the use of yeast harboring Mip1 mutations equivalent to the human ones to confirm their pathogenicity, identify the phenotypic defects caused by these mutations, and find both mechanisms and molecular compounds able to rescue the detrimental phenotype. A closing chapter will be dedicated to other polymerases found in yeast mitochondria, namely Pol ζ, Rev1 and Pol η, and to their genetic interactions with Mip1 necessary to maintain mtDNA stability and to avoid the accumulation of spontaneous or induced point mutations., (© 2023 The Authors. IUBMB Life published by Wiley Periodicals LLC on behalf of International Union of Biochemistry and Molecular Biology.)

Published

2023

8. TOF1 and RRM3 reveal a link between gene silencing and the pausing of replication forks.

Author

Shaban K, Dolson A, Fisher A, Lessard E, Sauty SM, and Yankulov K

Subjects

DNA-Binding Proteins genetics, Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, DNA Helicases genetics, DNA Replication genetics, Gene Silencing, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism

Abstract

Eukaryotic DNA replication is accompanied by the disassembly and reassembly of nucleosomes and the transmission of epigenetic marks to the newly assembled chromatids. Several histone chaperones, including CAF-1 and Asf1p, are central to these processes. On the other hand, replication forks pause at numerous positions throughout the genome, but it is not known if and how this pausing affects the reassembly and maintenance of chromatin structures. Here, we applied drug-free gene silencing assays to analyze the genetic interactions between CAC1, ASF1, and two genes that regulate the stability of the paused replisome (TOF1) and the resumption of elongation (RRM3). Our results show that TOF1 and RRM3 differentially interact with CAF-1 and ASF1 and that the deletions of TOF1 and RRM3 lead to reduced silencing and increased frequency of epigenetic conversions at three loci in the genome of S. cerevisiae. Our study adds details to the known activities of CAF-1 and Asf1p and suggests that the pausing of the replication fork can lead to epigenetic instability., (© 2023. The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2023

9. Sis2 regulates yeast replicative lifespan in a dose-dependent manner.

Author

Ölmez TT, Moreno DF, Liu P, Johnson ZM, McGinnis MM, Tu BP, Hochstrasser M, and Acar M

Subjects

Cell Cycle, DNA Replication genetics, Longevity genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism

Abstract

Application of microfluidic platforms facilitated high-precision measurements of yeast replicative lifespan (RLS); however, comparative quantification of lifespan across strain libraries has been missing. Here we microfluidically measure the RLS of 307 yeast strains, each deleted for a single gene. Despite previous reports of extended lifespan in these strains, we found that 56% of them did not actually live longer than the wild-type; while the remaining 44% showed extended lifespans, the degree of extension was often different from what was previously reported. Deletion of SIS2 gene led to the largest RLS increase observed. Sis2 regulated yeast lifespan in a dose-dependent manner, implying a role for the coenzyme A biosynthesis pathway in lifespan regulation. Introduction of the human PPCDC gene in the sis2Δ background neutralized the lifespan extension. RNA-seq experiments revealed transcriptional increases in cell-cycle machinery components in sis2Δ background. High-precision lifespan measurement will be essential to elucidate the gene network governing lifespan., (© 2023. The Author(s).)

Published

2023

10. Two independent DNA repair pathways cause mutagenesis in template switching deficient Saccharomyces cerevisiae.

Author

Jiang YK, Medley EA, and Brown GW

Subjects

Proliferating Cell Nuclear Antigen genetics, Proliferating Cell Nuclear Antigen metabolism, DNA Helicases genetics, DNA Repair, DNA Replication genetics, Mutagenesis, DNA Damage, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism

Abstract

Upon DNA replication stress, cells utilize the postreplication repair pathway to repair single-stranded DNA and maintain genome integrity. Postreplication repair is divided into 2 branches: error-prone translesion synthesis, signaled by proliferating cell nuclear antigen (PCNA) monoubiquitination, and error-free template switching, signaled by PCNA polyubiquitination. In Saccharomyces cerevisiae, Rad5 is involved in both branches of repair during DNA replication stress. When the PCNA polyubiquitination function of Rad5 s disrupted, Rad5 recruits translesion synthesis polymerases to stalled replication forks, resulting in mutagenic repair. Details of how mutagenic repair is carried out, as well as the relationship between Rad5-mediated mutagenic repair and the canonical PCNA-mediated mutagenic repair, remain to be understood. We find that Rad5-mediated mutagenic repair requires the translesion synthesis polymerase ζ but does not require other yeast translesion polymerase activities. Furthermore, we show that Rad5-mediated mutagenic repair is independent of PCNA binding by Rev1 and so is separable from canonical mutagenic repair. In the absence of error-free template switching, both modes of mutagenic repair contribute additively to replication stress response in a replication timing-independent manner. Cellular contexts where error-free template switching is compromised are not simply laboratory phenomena, as we find that a natural variant in RAD5 is defective in PCNA polyubiquitination and therefore defective in error-free repair, resulting in Rad5- and PCNA-mediated mutagenic repair. Our results highlight the importance of Rad5 in regulating spontaneous mutagenesis and genetic diversity in S. cerevisiae through different modes of postreplication repair., Competing Interests: Conflicts of interest The authors declare no conflict of interest., (© The Author(s) 2023. Published by Oxford University Press on behalf of The Genetics Society of America. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2023

11. DNA polymerase ε leading strand signature mutations result from defects in its proofreading activity.

Author

Johnson RE, Prakash L, and Prakash S

Subjects

DNA Polymerase III metabolism, DNA Polymerase II metabolism, DNA Replication genetics, Mutation, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins metabolism, Mutagenesis

Abstract

The evidence that purified pol2-M644G DNA polymerase (Pol)ε exhibits a highly elevated bias for forming T:dTTP mispairs over A:dATP mispairs and that yeast cells harboring this Polε mutation accumulate A > T signature mutations in the leading strand have been used to assign a role for Polε in replicating the leading strand. Here, we determine whether A > T signature mutations result from defects in Polε proofreading activity by analyzing their rate in Polε proofreading defective pol2-4 and pol2-M644G cells. Since purified pol2-4 Polε exhibits no bias for T:dTTP mispair formation, A > T mutations are expected to occur at a much lower rate in pol2-4 than in pol2-M644G cells if Polε replicated the leading strand. Instead, we find that the rate of A > T signature mutations are as highly elevated in pol2-4 cells as in pol2-M644G cells; furthermore, the highly elevated rate of A > T signature mutations is severely curtailed in the absence of PCNA ubiquitination or Polζ in both the pol2-M644G and pol2-4 strains. Altogether, our evidence supports the conclusion that the leading strand A > T signature mutations derive from defects in Polε proofreading activity and not from the role of Polε as a leading strand replicase, and it conforms with the genetic evidence for a major role of Polδ in replication of both the DNA strands., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

12. Changed life course upon defective replication of ribosomal RNA genes.

Author

Hattori M, Horigome C, Aspert T, Charvin G, and Kobayashi T

Subjects

Genes, rRNA, Cellular Senescence genetics, DNA, Ribosomal genetics, DNA Replication genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics

Abstract

Genome instability is a major cause of aging. In the budding yeast Saccharomyces cerevisiae, instability of the ribosomal RNA gene repeat (rDNA) is known to shorten replicative lifespan. In yeast, rDNA instability in an aging cell is associated with accumulation of extrachromosomal rDNA circles (ERCs) which titrate factors critical for lifespan maintenance. ERC accumulation is not detected in mammalian cells, where aging is linked to DNA damage. To distinguish effects of DNA damage from those of ERC accumulation on senescence, we re-analyzed a yeast strain with a replication initiation defect in the rDNA, which limits ERC multiplication. In aging cells of this strain (rARS-∆3) rDNA became unstable, as in wild-type cells, whereas significantly fewer ERCs accumulated. Single-cell aging analysis revealed that rARS-∆3 cells follow a linear survival curve and can have a wild-type replicative lifespan, although a fraction of the cells stopped dividing earlier than wild type. The doubling time of rARS-∆3 cells appears to increase in the final cell divisions. Our results suggest that senescence in rARS-∆3 is linked to the accumulation of DNA damage as in mammalian cells, rather than to elevated ERC level. Therefore, this strain should be a good model system to study ERC-independent aging.

Published

2023

13. Timing of Chromosome DNA Integration throughout the Yeast Cell Cycle.

Author

Tosato V, Rossi B, Sims J, and Bruschi CV

Subjects

Humans, DNA Breaks, Double-Stranded, Cell Cycle genetics, DNA Replication genetics, Translocation, Genetic, Chromosomes metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism

Abstract

The dynamic mechanism of cell uptake and genomic integration of exogenous linear DNA still has to be completely clarified, especially within each phase of the cell cycle. We present a study of integration events of double-stranded linear DNA molecules harboring at their ends sequence homologies to the host's genome, all throughout the cell cycle of the model organism Saccharomyces cerevisiae , comparing the efficiency of chromosomal integration of two types of DNA cassettes tailored for site-specific integration and bridge-induced translocation. Transformability increases in S phase regardless of the sequence homologies, while the efficiency of chromosomal integration during a specific cycle phase depends upon the genomic targets. Moreover, the frequency of a specific translocation between chromosomes XV and VIII strongly increased during DNA synthesis under the control of Pol32 polymerase. Finally, in the null POL32 double mutant, different pathways drove the integration in the various phases of the cell cycle and bridge-induced translocation was possible outside the S phase even without Pol32. The discovery of this cell-cycle dependent regulation of specific pathways of DNA integration, associated with an increase of ROS levels following translocation events, is a further demonstration of a sensing ability of the yeast cell in determining a cell-cycle-related choice of DNA repair pathways under stress.

Published

2023

14. Ribosomal DNA replication time coordinates completion of genome replication and anaphase in yeast.

Author

Kwan EX, Alvino GM, Lynch KL, Levan PF, Amemiya HM, Wang XS, Johnson SA, Sanchez JC, Miller MA, Croy M, Lee SB, Naushab M, Bedalov A, Cuperus JT, Brewer BJ, Queitsch C, and Raghuraman MK

Subjects

Anaphase, DNA, Ribosomal genetics, DNA, Ribosomal metabolism, Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, DNA-Binding Proteins metabolism, Protein Tyrosine Phosphatases genetics, Protein Tyrosine Phosphatases metabolism, Ribosomes metabolism, DNA Replication genetics, Virus Replication, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism

Abstract

Timely completion of genome replication is a prerequisite for mitosis, genome integrity, and cell survival. A challenge to this timely completion comes from the need to replicate the hundreds of untranscribed copies of rDNA that organisms maintain in addition to the copies required for ribosome biogenesis. Replication of these rDNA arrays is relegated to late S phase despite their large size, repetitive nature, and essentiality. Here, we show that, in Saccharomyces cerevisiae, reducing the number of rDNA repeats leads to early rDNA replication, which results in delaying replication elsewhere in the genome. Moreover, cells with early-replicating rDNA arrays and delayed genome-wide replication aberrantly release the mitotic phosphatase Cdc14 from the nucleolus and enter anaphase prematurely. We propose that rDNA copy number determines the replication time of the rDNA locus and that the release of Cdc14 upon completion of rDNA replication is a signal for cell cycle progression., Competing Interests: Declaration of interests C.Q. is a Cell Reports Advisory Board member, Ecology and Evolution., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

15. The evolving tale of Pol2 function.

Author

Gallitto M and Zhang Z

Subjects

Humans, DNA genetics, Exonucleases metabolism, Mutation, DNA Polymerase II genetics, DNA Polymerase II metabolism, DNA Replication genetics, Neoplasms genetics, Saccharomyces cerevisiae metabolism

Abstract

DNA replication is complex and highly regulated, and DNA replication errors can lead to human diseases such as cancer. DNA polymerase ε (polε) is a key player in DNA replication and contains a large subunit called POLE, which possesses both a DNA polymerase domain and a 3'-5' exonuclease domain (EXO). Mutations at the EXO domain and other missense mutations on POLE with unknown significance have been detected in a variety of human cancers. Based on cancer genome databases, Meng and colleagues (pp. 74-79) previously identified several missense mutations in POPS (pol2 family-specific catalytic core peripheral subdomain), and mutations at the conserved residues of yeast Pol2 ( pol2-REL) showed reduced DNA synthesis and growth. In this issue of Genes & Development , Meng and colleagues (pp. 74-79) found unexpectedly that mutations at the EXO domain rescue the growth defects of pol2-REL. They further discovered that EXO-mediated polymerase backtracking impedes forward movement of the enzyme when POPS is defective, revealing a novel interplay between the EXO domain and POPS of Pol2 for efficient DNA synthesis. Additional molecular insight into this interplay will likely inform the impact of cancer-associated mutations found in both the EXO domain and POPS on tumorigenesis and uncover future novel therapeutic strategies., (© 2023 Gallitto and Zhang; Published by Cold Spring Harbor Laboratory Press.)

Published

2023

16. Break-induced replication: unraveling each step.

Author

Liu L and Malkova A

Subjects

DNA, DNA Breaks, Double-Stranded, DNA Repair genetics, DNA Replication genetics, Humans, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism

Abstract

Break-induced replication (BIR) repairs one-ended double-strand DNA breaks through invasion into a homologous template followed by DNA synthesis. Different from S-phase replication, BIR copies the template DNA in a migrating displacement loop (D-loop) and results in conservative inheritance of newly synthesized DNA. This unusual mode of DNA synthesis makes BIR a source of various genetic instabilities like those associated with cancer in humans. This review focuses on recent progress in delineating the mechanism of Rad51-dependent BIR in budding yeast. In addition, we discuss new data that describe changes in BIR efficiency and fidelity on encountering replication obstacles as well as the implications of these findings for BIR-dependent processes such as telomere maintenance and the repair of collapsed replication forks., Competing Interests: Declaration of interests No interests are declared., (Copyright © 2022 Elsevier Ltd. All rights reserved.)

Published

2022

17. The long and short of rDNA and yeast replicative aging.

Author

Smith JS

Subjects

Aging, DNA Replication genetics, DNA, Ribosomal genetics, Silent Information Regulator Proteins, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Published

2022

18. Hypomorphic GINS3 variants alter DNA replication and cause Meier-Gorlin syndrome.

Author

McQuaid ME, Ahmed K, Tran S, Rousseau J, Shaheen R, Kernohan KD, Yuki KE, Grover P, Dreseris ES, Ahmed S, Dupuis L, Stimec J, Shago M, Al-Hassnan ZN, Tremblay R, Maass PG, Wilson MD, Grunebaum E, Boycott KM, Boisvert FM, Maddirevula S, Faqeih EA, Almanjomi F, Khan ZU, Alkuraya FS, Campeau PM, Kannu P, Campos EI, and Wurtele H

Subjects

Animals, Chromosomal Proteins, Non-Histone, Congenital Microtia, DNA Replication genetics, Growth Disorders, Humans, Mice, Minichromosome Maintenance Proteins genetics, Patella abnormalities, Micrognathism genetics, Saccharomyces cerevisiae

Abstract

The eukaryotic CDC45/MCM2-7/GINS (CMG) helicase unwinds the DNA double helix during DNA replication. The GINS subcomplex is required for helicase activity and is, therefore, essential for DNA replication and cell viability. Here, we report the identification of 7 individuals from 5 unrelated families presenting with a Meier-Gorlin syndrome-like (MGS-like) phenotype associated with hypomorphic variants of GINS3, a gene not previously associated with this syndrome. We found that MGS-associated GINS3 variants affecting aspartic acid 24 (D24) compromised cell proliferation and caused accumulation of cells in S phase. These variants shortened the protein half-life, altered key protein interactions at the replisome, and negatively influenced DNA replication fork progression. Yeast expressing MGS-associated variants of PSF3 (the yeast GINS3 ortholog) also displayed impaired growth, S phase progression defects, and decreased Psf3 protein stability. We further showed that mouse embryos homozygous for a D24 variant presented intrauterine growth retardation and did not survive to birth, and that fibroblasts derived from these embryos displayed accelerated cellular senescence. Taken together, our findings implicate GINS3 in the pathogenesis of MGS and support the notion that hypomorphic variants identified in this gene impaired cell and organismal growth by compromising DNA replication.

Published

2022

19. Yeast Stn1 promotes MCM to circumvent Rad53 control of the S phase checkpoint.

Author

Gasparayan H, Caridi C, Julius J, Feng W, Bachant J, and Nugent CI

Subjects

Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, Checkpoint Kinase 2 genetics, Checkpoint Kinase 2 metabolism, DNA Replication genetics, Minichromosome Maintenance Complex Component 7 genetics, Minichromosome Maintenance Complex Component 7 metabolism, Mutation, Protein Serine-Threonine Kinases, S Phase genetics, S Phase Cell Cycle Checkpoints genetics, Telomere-Binding Proteins metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism

Abstract

Treating yeast cells with the replication inhibitor hydroxyurea activates the S phase checkpoint kinase Rad53, eliciting responses that block DNA replication origin firing, stabilize replication forks, and prevent premature extension of the mitotic spindle. We previously found overproduction of Stn1, a subunit of the telomere-binding Cdc13-Stn1-Ten1 complex, circumvents Rad53 checkpoint functions in hydroxyurea, inducing late origin firing and premature spindle extension even though Rad53 is activated normally. Here, we show Stn1 overproduction acts through remarkably similar pathways compared to loss of RAD53, converging on the MCM complex that initiates origin firing and forms the catalytic core of the replicative DNA helicase. First, mutations affecting Mcm2 and Mcm5 block the ability of Stn1 overproduction to disrupt the S phase checkpoint. Second, loss of function stn1 mutations compensate rad53 S phase checkpoint defects. Third Stn1 overproduction suppresses a mutation in Mcm7. Fourth, stn1 mutants accumulate single-stranded DNA at non-telomeric genome locations, imposing a requirement for post-replication DNA repair. We discuss these interactions in terms of a model in which Stn1 acts as an accessory replication factor that facilitates MCM activation at ORIs and potentially also maintains MCM activity at replication forks advancing through challenging templates., (© 2022. The Author(s).)

Published

2022

20. The yeast Dbf4 Zn 2+ finger domain suppresses single-stranded DNA at replication forks initiated from a subset of origins.

Author

Bachant J, Hoffman EA, Caridi C, Nugent CI, and Feng W

Subjects

Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, DNA Replication genetics, DNA, Single-Stranded genetics, DNA, Single-Stranded metabolism, Protein Serine-Threonine Kinases, Replication Origin genetics, Zinc metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Dbf4 is the cyclin-like subunit for the Dbf4-dependent protein kinase (DDK), required for activating the replicative helicase at DNA replication origin that fire during S phase. Dbf4 also functions as an adaptor, targeting the DDK to different groups of origins and substrates. Here we report a genome-wide analysis of origin firing in a budding yeast mutant, dbf4-zn, lacking the Zn 2+ finger domain within the C-terminus of Dbf4. At one group of origins, which we call dromedaries, we observe an unanticipated DNA replication phenotype: accumulation of single-stranded DNA spanning ± 5kbp from the center of the origins. A similar accumulation of single-stranded DNA at origins occurs more globally in pri1-m4 mutants defective for the catalytic subunit of DNA primase and rad53 mutants defective for the S phase checkpoint following DNA replication stress. We propose the Dbf4 Zn 2+ finger suppresses single-stranded gaps at replication forks emanating from dromedary origins. Certain origins may impose an elevated requirement for the DDK to fully initiate DNA synthesis following origin activation. Alternatively, dbf4-zn may be defective for stabilizing/restarting replication forks emanating from dromedary origins during replication stress., (© 2022. The Author(s).)

Published

2022

21. Global genomic instability caused by reduced expression of DNA polymerase ε in yeast.

Author

Zhang K, Sui Y, Li WL, Chen G, Wu XC, Kokoska RJ, Petes TD, and Zheng DQ

Subjects

DNA Replication genetics, Genomic Instability genetics, Humans, Mutation, DNA Polymerase II metabolism, Saccharomyces cerevisiae metabolism

Abstract

SignificanceAlthough most studies of the genetic regulation of genome stability involve an analysis of mutations within the coding sequences of genes required for DNA replication or DNA repair, recent studies in yeast show that reduced levels of wild-type enzymes can also produce a mutator phenotype. By whole-genome sequencing and other methods, we find that reduced levels of the wild-type DNA polymerase ε in yeast greatly increase the rates of mitotic recombination, aneuploidy, and single-base mutations. The observed pattern of genome instability is different from those observed in yeast strains with reduced levels of the other replicative DNA polymerases, Pol α and Pol δ. These observations are relevant to our understanding of cancer and other diseases associated with genetic instability.

Published

2022

22. A helicase-tethered ORC flip enables bidirectional helicase loading.

Author

Gupta S, Friedman LJ, Gelles J, and Bell SP

Subjects

Binding Sites, DNA, Fungal metabolism, Minichromosome Maintenance Proteins metabolism, Origin Recognition Complex genetics, Origin Recognition Complex metabolism, Protein Binding, Protein Domains, Protein Multimerization, DNA Replication genetics, DNA, Fungal genetics, Minichromosome Maintenance Proteins genetics, Replication Origin genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism

Abstract

Replication origins are licensed by loading two Mcm2-7 helicases around DNA in a head-to-head conformation poised to initiate bidirectional replication. This process requires origin-recognition complex (ORC), Cdc6, and Cdt1. Although different Cdc6 and Cdt1 molecules load each helicase, whether two ORC proteins are required is unclear. Using colocalization single-molecule spectroscopy combined with single-molecule Förster resonance energy transfer (FRET), we investigated interactions between ORC and Mcm2-7 during helicase loading. In the large majority of events, we observed a single ORC molecule recruiting both Mcm2-7/Cdt1 complexes via similar interactions that end upon Cdt1 release. Between first- and second-helicase recruitment, a rapid change in interactions between ORC and the first Mcm2-7 occurs. Within seconds, ORC breaks the interactions mediating first Mcm2-7 recruitment, releases from its initial DNA-binding site, and forms a new interaction with the opposite face of the first Mcm2-7. This rearrangement requires release of the first Cdt1 and tethers ORC as it flips over the first Mcm2-7 to form an inverted Mcm2-7-ORC-DNA complex required for second-helicase recruitment. To ensure correct licensing, this complex is maintained until head-to-head interactions between the two helicases are formed. Our findings reconcile previous observations and reveal a highly coordinated series of events through which a single ORC molecule can load two oppositely oriented helicases., Competing Interests: SG, LF, JG, SB No competing interests declared, (© 2021, Gupta et al.)

Published

2021

23. Recombination-dependent replication: new perspectives from site-specific fork barriers.

Author

Carr A and Lambert S

Subjects

Recombination, Genetic, DNA Replication genetics, Saccharomyces cerevisiae genetics

Abstract

Replication stress (RS) is intrinsic to normal cell growth, is enhanced by exogenous factors and elevated in many cancer cells due to oncogene expression. Most genetic changes are a result of RS and the mechanisms by which cells tolerate RS has received considerable attention because of the link to cancer evolution and opportunities for cancer cell-specific therapeutic intervention. Site-specific replication fork barriers have provided unique insights into how cells respond to RS and their recent use has allowed a deeper understanding of the mechanistic and spatial mechanism that restart arrested forks and how these correlate with RS-dependent mutagenesis. Here we review recent data from site-specific fork arrest systems used in yeast and highlight their strengths and limitations., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published

2021

24. How asymmetric DNA replication achieves symmetrical fidelity.

Author

Zhou ZX, Lujan SA, Burkholder AB, St Charles J, Dahl J, Farrell CE, Williams JS, and Kunkel TA

Subjects

DNA Polymerase II metabolism, DNA Replication genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, DNA Mismatch Repair genetics, DNA Polymerase III metabolism, DNA, Fungal biosynthesis, Saccharomyces cerevisiae genetics

Abstract

Accurate DNA replication of an undamaged template depends on polymerase selectivity for matched nucleotides, exonucleolytic proofreading of mismatches, and removal of remaining mismatches via DNA mismatch repair (MMR). DNA polymerases (Pols) δ and ε have 3'-5' exonucleases into which mismatches are partitioned for excision in cis (intrinsic proofreading). Here we provide strong evidence that Pol δ can extrinsically proofread mismatches made by itself and those made by Pol ε, independently of both Pol δ's polymerization activity and MMR. Extrinsic proofreading across the genome is remarkably efficient. We report, with unprecedented accuracy, in vivo contributions of nucleotide selectivity, proofreading, and MMR to the fidelity of DNA replication in Saccharomyces cerevisiae. We show that extrinsic proofreading by Pol δ improves and balances the fidelity of the two DNA strands. Together, we depict a comprehensive picture of how nucleotide selectivity, proofreading, and MMR cooperate to achieve high and symmetrical fidelity on the two strands., (© 2021. This is a U.S. government work and not under copyright protection in the U.S.; foreign copyright protection may apply.)

Published

2021

25. Break-induced replication mechanisms in yeast and mammals.

Author

Wu X and Malkova A

Subjects

Animals, DNA Breaks, Double-Stranded, DNA Replication genetics, Mammals genetics, DNA Repair genetics, Saccharomyces cerevisiae genetics

Abstract

Break-induced replication (BIR) is a pathway specialized in repair of double-strand DNA breaks with only one end capable of invading homologous template that can arise following replication collapse, telomere erosion or DNA cutting by site-specific endonucleases. For a long time, yeast remained the only model system to study BIR. Studies in yeast demonstrated that BIR represents an unusual mode of DNA synthesis that is driven by a migrating bubble and leads to conservative inheritance of newly synthesized DNA. This unusual type of DNA synthesis leads to high levels of mutations and chromosome rearrangements. Recently, multiple examples of BIR were uncovered in mammalian cells that allowed the comparison of BIR between organisms. It appeared initially that BIR in mammalian cells is predominantly independent of RAD51, and therefore different from BIR that is predominantly Rad51-dependent in yeast. However, a series of systematic studies utilizing site-specific DNA breaks for BIR initiation in mammalian reporters led to the discovery of highly efficient RAD51-dependent BIR, allowing side-by side comparison with BIR in yeast which is the focus of this review., (Published by Elsevier Ltd.)

Published

2021

26. Chromosomal Mcm2-7 distribution and the genome replication program in species from yeast to humans.

Author

Foss EJ, Sripathy S, Gatbonton-Schwager T, Kwak H, Thiesen AH, Lao U, and Bedalov A

Subjects

Humans, Chromosomes, Fungal, Chromosomes, Human, DNA Replication genetics, Genome, Fungal, Minichromosome Maintenance Proteins genetics, Saccharomyces cerevisiae genetics

Abstract

The spatio-temporal program of genome replication across eukaryotes is thought to be driven both by the uneven loading of pre-replication complexes (pre-RCs) across the genome at the onset of S-phase, and by differences in the timing of activation of these complexes during S phase. To determine the degree to which distribution of pre-RC loading alone could account for chromosomal replication patterns, we mapped the binding sites of the Mcm2-7 helicase complex (MCM) in budding yeast, fission yeast, mouse and humans. We observed similar individual MCM double-hexamer (DH) footprints across the species, but notable differences in their distribution: Footprints in budding yeast were more sharply focused compared to the other three organisms, consistent with the relative sequence specificity of replication origins in S. cerevisiae. Nonetheless, with some clear exceptions, most notably the inactive X-chromosome, much of the fluctuation in replication timing along the chromosomes in all four organisms reflected uneven chromosomal distribution of pre-replication complexes., Competing Interests: The authors have declared that no competing interests exist.

Published

2021

27. Rad53 checkpoint kinase regulation of DNA replication fork rate via Mrc1 phosphorylation.

Author

McClure AW and Diffley JF

Subjects

DNA Damage, DNA-Binding Proteins metabolism, Mutation, Phosphorylation, Saccharomyces cerevisiae metabolism, Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, Checkpoint Kinase 2 genetics, DNA Replication genetics, Gene Expression Regulation, Fungal, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism

Abstract

The Rad53 DNA checkpoint protein kinase plays multiple roles in the budding yeast cell response to DNA replication stress. Key amongst these is its enigmatic role in safeguarding DNA replication forks. Using DNA replication reactions reconstituted with purified proteins, we show Rad53 phosphorylation of Sld3/7 or Dbf4-dependent kinase blocks replication initiation whilst phosphorylation of Mrc1 or Mcm10 slows elongation. Mrc1 phosphorylation is necessary and sufficient to slow replication forks in complete reactions; Mcm10 phosphorylation can also slow replication forks, but only in the absence of unphosphorylated Mrc1. Mrc1 stimulates the unwinding rate of the replicative helicase, CMG, and Rad53 phosphorylation of Mrc1 prevents this. We show that a phosphorylation-mimicking Mrc1 mutant cannot stimulate replication in vitro and partially rescues the sensitivity of a rad53 null mutant to genotoxic stress in vivo. Our results show that Rad53 protects replication forks in part by antagonising Mrc1 stimulation of CMG unwinding., Competing Interests: AM, JD No competing interests declared, (© 2021, McClure and Diffley.)

Published

2021

28. The structure of ORC-Cdc6 on an origin DNA reveals the mechanism of ORC activation by the replication initiator Cdc6.

Author

Feng X, Noguchi Y, Barbon M, Stillman B, Speck C, and Li H

Subjects

Amino Acid Sequence, Base Sequence, Cell Cycle Proteins chemistry, Cell Cycle Proteins metabolism, Cryoelectron Microscopy, DNA, Fungal chemistry, DNA, Fungal metabolism, DNA-Binding Proteins chemistry, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Models, Molecular, Nucleic Acid Conformation, Origin Recognition Complex chemistry, Origin Recognition Complex metabolism, Protein Binding, Protein Domains, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae ultrastructure, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins metabolism, Sequence Homology, Amino Acid, Sequence Homology, Nucleic Acid, Transcription Factors chemistry, Transcription Factors genetics, Transcription Factors metabolism, Cell Cycle Proteins genetics, DNA Replication genetics, DNA, Fungal genetics, Origin Recognition Complex genetics, Replication Origin genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics

Abstract

The Origin Recognition Complex (ORC) binds to sites in chromosomes to specify the location of origins of DNA replication. The S. cerevisiae ORC binds to specific DNA sequences throughout the cell cycle but becomes active only when it binds to the replication initiator Cdc6. It has been unclear at the molecular level how Cdc6 activates ORC, converting it to an active recruiter of the Mcm2-7 hexamer, the core of the replicative helicase. Here we report the cryo-EM structure at 3.3 Å resolution of the yeast ORC-Cdc6 bound to an 85-bp ARS1 origin DNA. The structure reveals that Cdc6 contributes to origin DNA recognition via its winged helix domain (WHD) and its initiator-specific motif. Cdc6 binding rearranges a short α-helix in the Orc1 AAA+ domain and the Orc2 WHD, leading to the activation of the Cdc6 ATPase and the formation of the three sites for the recruitment of Mcm2-7, none of which are present in ORC alone. The results illuminate the molecular mechanism of a critical biochemical step in the licensing of eukaryotic replication origins.

Published

2021

29. OriC-ENS: A sequence-based ensemble classifier for predicting origin of replication in S. cerevisiae.

Author

Azim SM, Haque MR, and Shatabda S

Subjects

DNA Replication genetics, Databases, Genetic, Genes, Fungal genetics, Saccharomyces cerevisiae genetics, Sequence Analysis, DNA

Abstract

DNA Replication plays the most crucial part in biological inheritance, ensuring an even flow of genetic information from parent to offspring. The beginning site of DNA Replication which is called the Origin of Replication (ORI), plays a significant role in understanding the molecular mechanisms and genomic analysis of DNA. Hence, it is paramount to accurately identify the origin of replication to gain a more accurate understanding of the biochemical and genomic properties of DNA. In this paper, We have proposed a new approach named OriC-ENS that uses sequence-based feature extraction techniques, K-mer, K-gapped Mono-Di, and Di Mono, and an ensemble classification technique that uses majority voting for the identification of Origin of Replication. We have used three SVM classifiers, one for the K-mer features and two more for K-Gapped Mono-Di and K-Gapped Di-mono features. Finally, we used majority voting to combine the prediction by each predictor. Experimental results on the S. Cerevisiae dataset have shown that our method achieves an accuracy of 91.62 % which outperforms other state-of-the-art methods by a significant margin. We have also tested our method using other evaluation metrics such as Matthews Correlation Coefficient (MCC), Area Under Curve(AUC), Sensitivity, and Specificity, where it has achieved a score of 0.83, 0.98, 0.90, and 0.92 respectively. We have further evaluated our model on an independent test set collected from OriDB, consisting of the sequences of Schizosaccharomyces pombe where we have seen that our model can predict the origin of replication efficiently and with great precision. We have made our python-based source code available at https://github.com/MehediAzim/OriC-ENS., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published

2021

30. Learning Yeast Genetics from Miro Radman.

Author

Haber JE

Subjects

DNA Damage genetics, DNA Repair genetics, DNA Replication genetics, Recombination, Genetic genetics, SOS Response, Genetics genetics, Saccharomyces cerevisiae genetics

Abstract

Miroslav Radman's far-sighted ideas have penetrated many aspects of our study of the repair of broken eukaryotic chromosomes. For over 35 years my lab has studied different aspects of the repair of chromosomal breaks in the budding yeast, Saccharomyces cerevisiae . From the start, we have made what we thought were novel observations that turned out to have been predicted by Miro's extraordinary work in the bacterium Escherichia coli and then later in the radiation-resistant Dienococcus radiodurans . In some cases, we have been able to extend some of his ideas a bit further.

Published

2021

31. Smc5/6 functions with Sgs1-Top3-Rmi1 to complete chromosome replication at natural pause sites.

Author

Agashe S, Joseph CR, Reyes TAC, Menolfi D, Giannattasio M, Waizenegger A, Szakal B, and Branzei D

Subjects

DNA Repair genetics, DNA-Binding Proteins metabolism, Endonucleases metabolism, Flap Endonucleases metabolism, RecQ Helicases metabolism, Saccharomyces cerevisiae metabolism, Cell Cycle Proteins metabolism, DNA Replication genetics, Genome, Fungal genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins metabolism

Abstract

Smc5/6 is essential for genome structural integrity by yet unknown mechanisms. Here we find that Smc5/6 co-localizes with the DNA crossed-strand processing complex Sgs1-Top3-Rmi1 (STR) at genomic regions known as natural pausing sites (NPSs) where it facilitates Top3 retention. Individual depletions of STR subunits and Smc5/6 cause similar accumulation of joint molecules (JMs) composed of reversed forks, double Holliday Junctions and hemicatenanes, indicative of Smc5/6 regulating Sgs1 and Top3 DNA processing activities. We isolate an intra-allelic suppressor of smc6-56 proficient in Top3 retention but affected in pathways that act complementarily with Sgs1 and Top3 to resolve JMs arising at replication termination. Upon replication stress, the smc6-56 suppressor requires STR and Mus81-Mms4 functions for recovery, but not Srs2 and Mph1 helicases that prevent maturation of recombination intermediates. Thus, Smc5/6 functions jointly with Top3 and STR to mediate replication completion and influences the function of other DNA crossed-strand processing enzymes at NPSs.

Published

2021

32. A non-radioactive DNA synthesis assay demonstrates that elements of the Sigma 1278b Mip1 mitochondrial DNA polymerase domain and C-terminal extension facilitate robust enzyme activity.

Author

Young MJ, Imperial RJ, Lakhi S, and Court DA

Subjects

Alleles, DNA Polymerase I genetics, DNA Replication physiology, DNA, Mitochondrial metabolism, Humans, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae Proteins genetics, DNA Polymerase I chemistry, DNA Polymerase I metabolism, DNA Replication genetics, DNA, Fungal genetics, DNA, Mitochondrial genetics, Enzyme Assays methods, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins metabolism

Abstract

The yeast DNA polymerase gamma, Mip1, is a useful tool to investigate the impact of orthologous human disease variants on mitochondrial DNA (mtDNA) replication. However, Mip1 is characterized by a C-terminal extension (CTE) that is not found on orthologous metazoan DNA polymerases, and the CTE is required for robust enzymatic activity. Two MIP1 alleles exist in standard yeast strains, encoding Mip1[S] or Mip1[Σ]. Mip1[S] is associated with reduced mtDNA stability and increased error rates in vivo. Although the Mip1[S] allele was initially identified in S288c, the Mip1[Σ] allele is widely present among available yeast genome sequences, suggesting that it is the wild-type (WT) allele. We developed a novel non-radioactive polymerase gamma assay to assess Mip1 functioning at its intracellular location, the mitochondrial membrane. Membrane fractions were isolated from yeast cells expressing full-length or CTE truncation variants of Mip1[S] or a chimeric Mip1[S] isoform harboring the Mip1[Σ]-specific T661 residue (cMip1 T661). Relative incorporation of digoxigenin (DIG)-11-deoxyuridine monophosphate (DIG-dUMP) by cMip1 T661 was higher than that by Mip1[S]. A cMip1 T661variant lacking 175 C-terminal residues maintained WT levels of DIG-dUMP incorporation, whereas the C-terminal variant lacking 205 residues displayed a significant decrease in incorporation. Newly synthesized DIG-labeled DNA decreased during later phases of reactions carried out at 37°C, suggesting temperature-sensitive destabilization of the polymerase domain and/or increased shuttling of the nascent DNA into the exonuclease domain. Comparative analysis of Mip1 enzyme functions using our novel assay has further demonstrated the importance of the CTE and T661 encoded by MIP1[Σ] in yeast mtDNA replication., (© 2020 John Wiley & Sons, Ltd.)

Published

2021

33. DNA replication origins retain mobile licensing proteins.

Author

Sánchez H, McCluskey K, van Laar T, van Veen E, Asscher FM, Solano B, Diffley JFX, and Dekker NH

Subjects

Algorithms, Binding Sites genetics, Cell Cycle Proteins metabolism, DNA, Fungal genetics, DNA, Fungal metabolism, DNA-Binding Proteins metabolism, Minichromosome Maintenance Proteins metabolism, Models, Genetic, Origin Recognition Complex metabolism, Protein Binding, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Cell Cycle Proteins genetics, DNA Replication genetics, DNA-Binding Proteins genetics, Minichromosome Maintenance Proteins genetics, Origin Recognition Complex genetics, Replication Origin genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics

Abstract

DNA replication in eukaryotes initiates at many origins distributed across each chromosome. Origins are bound by the origin recognition complex (ORC), which, with Cdc6 and Cdt1, recruits and loads the Mcm2-7 (MCM) helicase as an inactive double hexamer during G1 phase. The replisome assembles at the activated helicase in S phase. Although the outline of replisome assembly is understood, little is known about the dynamics of individual proteins on DNA and how these contribute to proper complex formation. Here we show, using single-molecule optical trapping and confocal microscopy, that yeast ORC is a mobile protein that diffuses rapidly along DNA. Origin recognition halts this search process. Recruitment of MCM molecules in an ORC- and Cdc6-dependent fashion results in slow-moving ORC-MCM intermediates and MCMs that rapidly scan the DNA. Following ATP hydrolysis, salt-stable loading of MCM single and double hexamers was seen, both of which exhibit salt-dependent mobility. Our results demonstrate that effective helicase loading relies on an interplay between protein diffusion and origin recognition, and suggest that MCM is stably loaded onto DNA in multiple forms.

Published

2021

34. The secondary-structured DNA-binding activity of Dna2 endonuclease/helicase is critical to cell growth under replication stress.

Author

Park S, Karatayeva N, Demin AA, Munashingha PR, and Seo YS

Subjects

Biocatalysis, Cell Cycle genetics, DNA Helicases chemistry, DNA Helicases metabolism, DNA, Fungal chemistry, DNA, Fungal metabolism, Endonucleases chemistry, Endonucleases metabolism, Intracellular Signaling Peptides and Proteins genetics, Intracellular Signaling Peptides and Proteins metabolism, Models, Molecular, Mutation, Nucleic Acid Conformation, Oligonucleotides genetics, Oligonucleotides metabolism, Protein Binding, Protein Domains, Protein Serine-Threonine Kinases genetics, Protein Serine-Threonine Kinases metabolism, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae growth & development, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins metabolism, Substrate Specificity, DNA Helicases genetics, DNA Replication genetics, DNA, Fungal genetics, Endonucleases genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics

Abstract

Dna2 can efficiently process 5' flaps containing DNA secondary structure using coordinated action of the three biochemical activities: the N-terminally encoded DNA-binding activity and the C-terminally encoded endonuclease and helicase activities. In this study, we investigated the cross talk among the three functional domains using a variety of dna2 mutant alleles and enzymes derived thereof. We found that disruption of the catalytic activities of Dna2 activated Dna2-dependent checkpoint, residing in the N-terminal domain. This checkpoint activity contributed to growth defects of dna2 catalytic mutants, revealing the presence of an intramolecular functional cross talk in Dna2. The N-terminal domain of Dna2 bound specifically to substrates that mimic DNA replication fork intermediates, including Holliday junctions. Using site-directed mutagenesis of the N-terminal domain of Dna2, we discovered that five consecutive basic amino acid residues were essential for the ability of Dna2 to bind hairpin DNA in vitro. Mutant cells expressing the dna2 allele containing all five basic residues substituted with alanine displayed three distinct phenotypes: (i) temperature-sensitive growth defects, (ii) bypass of S-phase arrest, and (iii) increased sensitivity to DNA-damaging agents. Taken together, our results indicate that the interplay between the N-terminal regulatory and C-terminal catalytic domains of Dna2 plays an important role in vivo, especially when cells are placed under replication stress., (© 2020 The Authors. The FEBS Journal published by John Wiley & Sons Ltd on behalf of Federation of European Biochemical Societies.)

Published

2021

35. High-fidelity DNA ligation enforces accurate Okazaki fragment maturation during DNA replication.

Author

Williams JS, Tumbale PP, Arana ME, Rana JA, Williams RS, and Kunkel TA

Subjects

Acetyltransferases metabolism, DNA Ligase ATP metabolism, DNA Ligases, DNA Mismatch Repair genetics, DNA Replication genetics, DNA-Directed DNA Polymerase metabolism, Flap Endonucleases metabolism, Membrane Proteins metabolism, Mutagenesis, Mutation, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins metabolism, DNA metabolism, DNA Replication physiology, DNA, Fungal metabolism, Saccharomyces cerevisiae metabolism

Abstract

DNA ligase 1 (LIG1, Cdc9 in yeast) finalizes eukaryotic nuclear DNA replication by sealing Okazaki fragments using DNA end-joining reactions that strongly discriminate against incorrectly paired DNA substrates. Whether intrinsic ligation fidelity contributes to the accuracy of replication of the nuclear genome is unknown. Here, we show that an engineered low-fidelity LIG1 Cdc9 variant confers a novel mutator phenotype in yeast typified by the accumulation of single base insertion mutations in homonucleotide runs. The rate at which these additions are generated increases upon concomitant inactivation of DNA mismatch repair, or by inactivation of the Fen1 Rad27 Okazaki fragment maturation (OFM) nuclease. Biochemical and structural data establish that LIG1 Cdc9 normally avoids erroneous ligation of DNA polymerase slippage products, and this protection is compromised by mutation of a LIG1 Cdc9 high-fidelity metal binding site. Collectively, our data indicate that high-fidelity DNA ligation is required to prevent insertion mutations, and that this may be particularly critical following strand displacement synthesis during the completion of OFM.

Published

2021

36. Mechanism of auto-inhibition and activation of Mec1 ATR checkpoint kinase.

Author

Tannous EA, Yates LA, Zhang X, and Burgers PM

Subjects

Amino Acid Sequence genetics, Cryoelectron Microscopy, DNA Damage genetics, DNA Replication genetics, Enzyme Activation genetics, Intracellular Signaling Peptides and Proteins genetics, Phosphatidylinositol 3-Kinases metabolism, Protein Conformation, Protein Serine-Threonine Kinases genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Adaptor Proteins, Signal Transducing metabolism, Cell Cycle Checkpoints genetics, Cell Cycle Proteins metabolism, DNA Repair genetics, Intracellular Signaling Peptides and Proteins metabolism, Protein Serine-Threonine Kinases metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

In response to DNA damage or replication fork stalling, the basal activity of Mec1 ATR is stimulated in a cell-cycle-dependent manner, leading to cell-cycle arrest and the promotion of DNA repair. Mec1 ATR dysfunction leads to cell death in yeast and causes chromosome instability and embryonic lethality in mammals. Thus, ATR is a major target for cancer therapies in homologous recombination-deficient cancers. Here we identify a single mutation in Mec1, conserved in ATR, that results in constitutive activity. Using cryo-electron microscopy, we determine the structures of this constitutively active form (Mec1(F2244L)-Ddc2) at 2.8 Å and the wild type at 3.8 Å, both in complex with Mg 2+ -AMP-PNP. These structures yield a near-complete atomic model for Mec1-Ddc2 and uncover the molecular basis for low basal activity and the conformational changes required for activation. Combined with biochemical and genetic data, we discover key regulatory regions and propose a Mec1 activation mechanism.

Published

2021

37. Recombination and Pol ζ Rescue Defective DNA Replication upon Impaired CMG Helicase-Pol ε Interaction.

Author

Denkiewicz-Kruk M, Jedrychowska M, Endo S, Araki H, Jonczyk P, Dmowski M, and Fijalkowska IJ

Subjects

Cell Survival genetics, Cell Survival radiation effects, DNA Polymerase II genetics, DNA Replication radiation effects, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, DNA-Directed DNA Polymerase metabolism, Frameshifting, Ribosomal genetics, Frameshifting, Ribosomal radiation effects, G2 Phase Cell Cycle Checkpoints genetics, Minichromosome Maintenance Proteins metabolism, Mutagenesis, Mutation, Mutation Rate, Nuclear Proteins genetics, Protein Binding, Rad52 DNA Repair and Recombination Protein genetics, Rad52 DNA Repair and Recombination Protein metabolism, Recombination, Genetic radiation effects, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae radiation effects, Saccharomyces cerevisiae Proteins genetics, Synthetic Lethal Mutations genetics, DNA Helicases metabolism, DNA Polymerase II metabolism, DNA Replication genetics, Nuclear Proteins metabolism, Recombination, Genetic genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

The CMG complex (Cdc45, Mcm2-7, GINS (Psf1, 2, 3, and Sld5)) is crucial for both DNA replication initiation and fork progression. The CMG helicase interaction with the leading strand DNA polymerase epsilon (Pol ε) is essential for the preferential loading of Pol ε onto the leading strand, the stimulation of the polymerase, and the modulation of helicase activity. Here, we analyze the consequences of impaired interaction between Pol ε and GINS in Saccharomyces cerevisiae cells with the psf1-100 mutation. This significantly affects DNA replication activity measured in vitro, while in vivo, the psf1-100 mutation reduces replication fidelity by increasing slippage of Pol ε, which manifests as an elevated number of frameshifts. It also increases the occurrence of single-stranded DNA (ssDNA) gaps and the demand for homologous recombination. The psf1-100 mutant shows elevated recombination rates and synthetic lethality with rad52Δ . Additionally, we observe increased participation of DNA polymerase zeta (Pol ζ) in DNA synthesis. We conclude that the impaired interaction between GINS and Pol ε requires enhanced involvement of error-prone Pol ζ, and increased participation of recombination as a rescue mechanism for recovery of impaired replication forks.

Published

2020

38. Saccharomyces cerevisiae rDNA as super-hub: the region where replication, transcription and recombination meet.

Author

Egidi A, Di Felice F, and Camilloni G

Subjects

Saccharomyces cerevisiae Proteins metabolism, DNA Replication genetics, DNA, Ribosomal genetics, Recombination, Genetic, Saccharomyces cerevisiae genetics, Transcription, Genetic

Abstract

Saccharomyces cerevisiae ribosomal DNA, the repeated region where rRNAs are synthesized by about 150 encoding units, hosts all the protein machineries responsible for the main DNA transactions such as replication, transcription and recombination. This and its repetitive nature make rDNA a unique and complex genetic locus compared to any other. All the different molecular machineries acting in this locus need to be accurately and finely controlled and coordinated and for this reason rDNA is one of the most impressive examples of highly complex molecular regulated loci. The region in which the large molecular complexes involved in rDNA activity and/or regulation are recruited is extremely small: that is, the 2.5 kb long intergenic spacer, interrupting each 35S RNA coding unit from the next. All S. cerevisiae RNA polymerases (I, II and III) transcribing the different genetic rDNA elements are recruited here; a sequence responsible for each rDNA unit replication, which needs its molecular apparatus, also localizes here; moreover, it is noteworthy that the rDNA replication proceeds almost unidirectionally because each replication fork is stopped in the so-called replication fork barrier. These localized fork blocking events induce, with a given frequency, the homologous recombination process by which cells maintain a high identity among the rDNA repeated units. Here, we describe the different processes involving the rDNA locus, how they influence each other and how these mutual interferences are highly regulated and coordinated. We propose that an rDNA conformation as a super-hub could help in optimizing the micro-environment for all basic DNA transactions.

Published

2020

39. Genetic Characterization of Three Distinct Mechanisms Supporting RNA-Driven DNA Repair and Modification Reveals Major Role of DNA Polymerase ζ.

Author

Meers C, Keskin H, Banyai G, Mazina O, Yang T, Gombolay AL, Mukherjee K, Kaparos EI, Newnam G, Mazin A, and Storici F

Subjects

Adolescent, Adult, DNA ultrastructure, DNA Breaks, Double-Stranded, DNA Repair genetics, DNA Replication genetics, DNA, Complementary genetics, DNA-Directed DNA Polymerase genetics, DNA-Directed DNA Polymerase ultrastructure, Genomic Instability genetics, Humans, Middle Aged, RNA ultrastructure, Rad52 DNA Repair and Recombination Protein genetics, Young Adult, DNA genetics, RNA genetics, Saccharomyces cerevisiae genetics

Abstract

DNA double-stranded breaks (DSBs) are dangerous lesions threatening genomic stability. Fidelity of DSB repair is best achieved by recombination with a homologous template sequence. In yeast, transcript RNA was shown to template DSB repair of DNA. However, molecular pathways of RNA-driven repair processes remain obscure. Utilizing assays of RNA-DNA recombination with and without an induced DSB in yeast DNA, we characterize three forms of RNA-mediated genomic modifications: RNA- and cDNA-templated DSB repair (R-TDR and c-TDR) using an RNA transcript or a DNA copy of the RNA transcript for DSB repair, respectively, and a new mechanism of RNA-templated DNA modification (R-TDM) induced by spontaneous or mutagen-induced breaks. While c-TDR requires reverse transcriptase, translesion DNA polymerase ζ (Pol ζ) plays a major role in R-TDR, and it is essential for R-TDM. This study characterizes mechanisms of RNA-DNA recombination, uncovering a role of Pol ζ in transferring genetic information from transcript RNA to DNA., Competing Interests: Declaration of Interests The authors declare no competing interests., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2020

40. Targeted Diversification in the S. cerevisiae Genome with CRISPR-Guided DNA Polymerase I.

Author

Tou CJ, Schaffer DV, and Dueber JE

Subjects

Base Sequence, Chromosomes, Fungal genetics, DNA Replication genetics, Deoxyribonuclease I genetics, Escherichia coli genetics, Gene Editing methods, Genetic Loci, Mutagenesis, Nucleotides genetics, Point Mutation, CRISPR-Cas Systems, DNA Polymerase I genetics, Genome, Fungal, RNA, Guide, CRISPR-Cas Systems genetics, Saccharomyces cerevisiae genetics

Abstract

New technologies to target nucleotide diversification in vivo are promising enabling strategies to perform directed evolution for engineering applications and forward genetics for addressing biological questions. Recently, we reported EvolvR-a system that employs CRISPR-guided Cas9 nickases fused to nick-translating, error-prone DNA polymerases to diversify targeted genomic loci-in E. coli . As CRISPR-Cas9 has shown activity across diverse cell types, EvolvR has the potential to be ported into other organisms, including eukaryotes, if nick-translating polymerases can be active across species. Here, we implement and characterize EvolvR's function in Saccharomyces cerevisiae , representing a key first step to enable EvolvR-mediated mutagenesis in eukaryotes. This advance will be useful for mutagenesis of user-defined loci in the yeast chromosomes for both engineering and basic research applications, and it furthermore provides a platform to develop the EvolvR technology for performance in higher eukaryotes.

Published

2020

41. A genome-wide screen identifies genes that suppress the accumulation of spontaneous mutations in young and aged yeast cells.

Author

Novarina D, Janssens GE, Bokern K, Schut T, van Oerle NC, Kazemier HG, Veenhoff LM, and Chang M

Subjects

DNA Replication genetics, Flap Endonucleases genetics, Gene Ontology, Genetic Techniques, Mutagenesis, Mutation, Mutation Accumulation, Nuclear Pore Complex Proteins genetics, Saccharomyces cerevisiae physiology, Single-Strand Specific DNA and RNA Endonucleases genetics, Amino Acid Transport Systems, Basic genetics, Cellular Senescence genetics, Genomic Instability genetics, Membrane Proteins genetics, Mutation Rate, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics

Abstract

To ensure proper transmission of genetic information, cells need to preserve and faithfully replicate their genome, and failure to do so leads to genome instability, a hallmark of both cancer and aging. Defects in genes involved in guarding genome stability cause several human progeroid syndromes, and an age-dependent accumulation of mutations has been observed in different organisms, from yeast to mammals. However, it is unclear whether the spontaneous mutation rate changes during aging and whether specific pathways are important for genome maintenance in old cells. We developed a high-throughput replica-pinning approach to screen for genes important to suppress the accumulation of spontaneous mutations during yeast replicative aging. We found 13 known mutation suppression genes, and 31 genes that had no previous link to spontaneous mutagenesis, and all acted independently of age. Importantly, we identified PEX19, encoding an evolutionarily conserved peroxisome biogenesis factor, as an age-specific mutation suppression gene. While wild-type and pex19Δ young cells have similar spontaneous mutation rates, aged cells lacking PEX19 display an elevated mutation rate. This finding suggests that functional peroxisomes may be important to preserve genome integrity specifically in old cells., (© 2019 The Authors. Aging Cell published by Anatomical Society and John Wiley & Sons Ltd.)

Published

2020

42. Measuring the Replicative Lifespan of Saccharomyces cerevisiae Using the HYAA Microfluidic Platform.

Author

Yu R, Jo MC, and Dang W

Subjects

Cell Division genetics, Longevity genetics, Saccharomyces cerevisiae Proteins genetics, Cellular Senescence genetics, DNA Replication genetics, Microfluidics methods, Saccharomyces cerevisiae genetics

Abstract

The replicative aging of the budding yeast, Saccharomyces cerevisiae, has been a useful model for dissecting the molecular mechanisms of the aging process. Traditionally, the replicative lifespan (RLS) is measured by manually dissecting mother cells from daughter cells, which is a very tedious process. Since 2012, several microfluidic systems have been developed to automate the dissection process, significantly accelerating RLS determination. Here, we describe a detailed protocol of RLS measurement using a ommercially available microfluidic system based on the HYAA chip design, which enables data collection of up to 8000 cells in a single experiment.

Published

2020

43. Fork pausing complex engages topoisomerases at the replisome.

Author

Shyian M, Albert B, Zupan AM, Ivanitsa V, Charbonnet G, Dilg D, and Shore D

Subjects

Cell Cycle Proteins metabolism, DNA Helicases metabolism, DNA Topoisomerases, Type I metabolism, DNA-Binding Proteins metabolism, Mutation, Protein Transport, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, DNA Replication genetics, DNA Topoisomerases metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism

Abstract

Replication forks temporarily or terminally pause at hundreds of hard-to-replicate regions around the genome. A conserved pair of budding yeast replisome components Tof1-Csm3 (fission yeast Swi1-Swi3 and human TIMELESS-TIPIN) act as a "molecular brake" and promote fork slowdown at proteinaceous replication fork barriers (RFBs), while the accessory helicase Rrm3 assists the replisome in removing protein obstacles. Here we show that the Tof1-Csm3 complex promotes fork pausing independently of Rrm3 helicase by recruiting topoisomerase I (Top1) to the replisome. Topoisomerase II (Top2) partially compensates for the pausing decrease in cells when Top1 is lost from the replisome. The C terminus of Tof1 is specifically required for Top1 recruitment to the replisome and fork pausing but not for DNA replication checkpoint (DRC) activation. We propose that forks pause at proteinaceous RFBs through a "sTOP" mechanism ("slowing down with topoisomerases I-II"), which we show also contributes to protecting cells from topoisomerase-blocking agents., (© 2020 Shyian et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2020

44. Recombinant expression and characterization of yeast Mrc1, a DNA replication checkpoint mediator.

Author

Li L and Zhang Z

Subjects

Cell Cycle Proteins isolation & purification, Recombinant Proteins genetics, Recombinant Proteins isolation & purification, Saccharomyces cerevisiae Proteins isolation & purification, Cell Cycle Proteins genetics, DNA Replication genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics

Abstract

In Saccharomyces cerevisiae , Mrc1 (homolog of human Claspin and mediator of replication checkpoint) is not only a part of the replication machine, but also participates in the replication stress response when DNA replication is blocked by hydroxyurea. Since Mrc1 is expressed in a small amount in cells and has many proteins interacting with it as a mediator, it is difficult to obtain Mrc1 with high concentration and purity. This article reports the purification of a stable truncation of Mrc1 and the full length Mrc1. High concentration and high purity of Mrc1 was obtained and the three-dimensional structure of Mrc1 was analyzed, which is a ring with a hole in the center. At the same time, we found that Mrc1 has an interaction with Rad24-RFC a clamp loader in the replication checkpoint, and can form a complex with it, implying that we can assemble large replication checkpoint complexes in vitro . These results initially reveal the ring structure of Mrc1 and its interaction with Rad24-RFC in replication checkpoints in S. cerevisiae .

Published

2020

45. Dysfunctional CAF-I reveals its role in cell cycle progression and differential regulation of gene silencing.

Author

Rowlands H, Shaban K, Cheng A, Foster B, and Yankulov K

Subjects

CDC2 Protein Kinase metabolism, Cell Cycle Proteins metabolism, Cell Division genetics, Chromatin genetics, Chromatin Assembly Factor-1 metabolism, DNA Damage genetics, DNA Damage radiation effects, DNA Replication genetics, Genes, Mating Type, Fungal, Mannose-Binding Lectins genetics, Mannose-Binding Lectins metabolism, Mutation, Phenotype, Phosphorylation, Proliferating Cell Nuclear Antigen metabolism, Protein Serine-Threonine Kinases metabolism, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae radiation effects, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Silent Information Regulator Proteins, Saccharomyces cerevisiae genetics, Silent Information Regulator Proteins, Saccharomyces cerevisiae metabolism, Sirtuin 2 genetics, Sirtuin 2 metabolism, Telomere metabolism, Cell Cycle genetics, Chromatin metabolism, Chromatin Assembly Factor-1 genetics, Gene Silencing, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae growth & development

Abstract

Chromatin Assembly Factor I (CAF-I) plays a central role in the reassembly of H3/H4 histones during DNA replication. In S. cerevisiae CAF-I is not essential and its loss is associated with reduced gene silencing at telomeres and increased sensitivity to DNA damage. Two kinases, Cyclin Dependent Kinase (CDK) and Dbf4-Dependent Kinase (DDK), are known to phosphorylate the Cac1p subunit of CAF-I, but their role in the regulation of CAF-I activity is not well understood. In this study we systematically mutated the phosphorylation target sites of these kinases. We show that concomitant mutations of the CDK and DDK target sites of Cac1p lead to growth retardation and significant cell cycle defects, altered cell morphology and increased sensitivity to DNA damage. Surprisingly, some mutations also produced flocculation, a phenotype that is lost in most laboratory strains, and displayed elevated expression of FLO genes. None of these effects is observed upon the destruction of CAF-I. In contrast, the mutations that caused flocculation did not affect gene silencing at the mating type and subtelomeric loci. We conclude that dysfunctional CAF-I produces severe phenotypes, which reveal a possible role of CAF-I in the coordination of DNA replication, chromatin reassembly and cell cycle progression. Our study highlights the role of phosphorylation of Cac1p by CDK and a putative role for DDK in the transmission and re-assembly of chromatin during DNA replication.

Published

2019

46. In Vitro Reconstitution Defines the Minimal Requirements for Cdc48-Dependent Disassembly of the CMG Helicase in Budding Yeast.

Author

Mukherjee PP and Labib KPM

Subjects

DNA Helicases genetics, DNA Replication genetics, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, In Vitro Techniques, Minichromosome Maintenance Complex Component 7 genetics, Nuclear Proteins genetics, Nuclear Proteins metabolism, Nucleocytoplasmic Transport Proteins genetics, Nucleocytoplasmic Transport Proteins metabolism, Recombinant Proteins genetics, Recombinant Proteins metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Valosin Containing Protein genetics, Vesicular Transport Proteins genetics, Vesicular Transport Proteins metabolism, DNA Helicases metabolism, F-Box Proteins metabolism, Minichromosome Maintenance Complex Component 7 metabolism, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Ubiquitination genetics, Valosin Containing Protein metabolism

Abstract

Disassembly of the replisome is the final step of chromosome duplication in eukaryotes. In budding yeast and metazoa, cullin ubiquitin ligases are required to ubiquitylate the Cdc45-MCM-GINS (CMG) helicase that lies at the heart of the replisome, leading to a disassembly reaction that is dependent upon the ATPase known as Cdc48 or p97. Here, we describe the reconstitution of replisome disassembly, using a purified complex of the budding yeast replisome in association with the cullin ligase SCF Dia2 . Upon addition of E1 and E2 enzymes, together with ubiquitin and ATP, the CMG helicase is ubiquitylated on its Mcm7 subunit. Subsequent addition of Cdc48, together with its cofactors Ufd1-Npl4, drives efficient disassembly of ubiquitylated CMG, thereby recapitulating the steps of replisome disassembly that are observed in vivo. Our findings define the minimal requirements for disassembly of the eukaryotic replisome and provide a model system for studying the disassembly of protein complexes by Cdc48-Ufd1-Npl4., (Copyright © 2019 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2019

47. Yeast PAF1 complex counters the pol III accumulation and replication stress on the tRNA genes.

Author

Bhalla P, Shukla A, Vernekar DV, Arimbasseri AG, Sandhu KS, and Bhargava P

Subjects

DNA Damage genetics, Gene Deletion, Histones metabolism, Methylation, Nuclear Proteins deficiency, Nuclear Proteins genetics, Saccharomyces cerevisiae Proteins genetics, Transcription, Genetic, DNA Replication genetics, Nuclear Proteins metabolism, RNA Polymerase III metabolism, RNA, Transfer genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Stress, Physiological genetics

Abstract

The RNA polymerase (pol) III transcribes mostly short, house-keeping genes, which produce stable, non-coding RNAs. The tRNAs genes, highly transcribed by pol III in vivo are known replication fork barriers. One of the transcription factors, the PAF1C (RNA polymerase II associated factor 1 complex) is reported to associate with pol I and pol II and influence their transcription. We found low level PAF1C occupancy on the yeast pol III-transcribed genes, which is not correlated with nucleosome positions, pol III occupancy and transcription. PAF1C interacts with the pol III transcription complex and causes pol III loss from the genes under replication stress. Genotoxin exposure causes pol III but not Paf1 loss from the genes. In comparison, Paf1 deletion leads to increased occupancy of pol III, γ-H2A and DNA pol2 in gene-specific manner. Paf1 restricts the accumulation of pol III by influencing the pol III pause on the genes, which reduces the pol III barrier to the replication fork progression.

Published

2019

48. RNase H activities counteract a toxic effect of Polymerase η in cells replicating with depleted dNTP pools.

Author

Meroni A, Nava GM, Bianco E, Grasso L, Galati E, Bosio MC, Delmastro D, Muzi-Falconi M, and Lazzaro F

Subjects

Apoptosis, DNA Damage genetics, DNA Repair genetics, Deoxyribonucleotides genetics, G2 Phase Cell Cycle Checkpoints genetics, Humans, DNA Replication genetics, DNA-Directed DNA Polymerase genetics, Ribonuclease H genetics, Saccharomyces cerevisiae genetics

Abstract

RNA:DNA hybrids are transient physiological intermediates that arise during several cellular processes such as DNA replication. In pathological situations, they may stably accumulate and pose a threat to genome integrity. Cellular RNase H activities process these structures to restore the correct DNA:DNA sequence. Yeast cells lacking RNase H are negatively affected by depletion of deoxyribonucleotide pools necessary for DNA replication. Here we show that the translesion synthesis DNA polymerase η (Pol η) plays a role in DNA replication under low deoxyribonucleotides condition triggered by hydroxyurea. In particular, the catalytic reaction performed by Pol η is detrimental for RNase H deficient cells, causing DNA damage checkpoint activation and G2/M arrest. Moreover, a Pol η mutant allele with enhanced ribonucleotide incorporation further exacerbates the sensitivity to hydroxyurea of cells lacking RNase H activities. Our data are compatible with a model in which Pol η activity facilitates the formation or stabilization of RNA:DNA hybrids at stalled replication forks. However, in a scenario where RNase H activity fails to restore DNA, these hybrids become highly toxic for cells., (© The Author(s) 2019. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2019

49. In yeast cells arrested at the early S-phase by hydroxyurea, rRNA gene promoters and chromatin are poised for transcription while rRNA synthesis is compromised.

Author

Charton R, Muguet A, Griesenbeck J, Smerdon MJ, and Conconi A

Subjects

Cell Cycle Checkpoints genetics, Cell Division genetics, DNA Replication genetics, DNA, Ribosomal genetics, RNA Polymerase I genetics, RNA, Ribosomal genetics, S Phase drug effects, S Phase genetics, Saccharomyces cerevisiae drug effects, Saccharomyces cerevisiae Proteins genetics, Cell Cycle Checkpoints drug effects, Chromatin genetics, Genes, rRNA genetics, Hydroxyurea pharmacology, Promoter Regions, Genetic genetics, Saccharomyces cerevisiae genetics, Transcription, Genetic genetics

Abstract

Hydroxyurea (HU) is an inhibitor of ribonucleotide reductase that is used as a chemotherapeutic agent to treat a number of chronic diseases. Addition of HU to cell cultures causes reduction of the dNTP cellular pool below levels that are required for DNA replication. This trigger dividing cells to arrest in early S-phase of the cell cycle. Cell division hinges on ribosome biogenesis, which is tightly regulated by rRNA synthesis. Remarkably, HU represses the expression of some genes the products of which are required for rRNA maturation. To gain more information on the cellular response to HU, we employed the yeast Saccharomyces cerevisiae as model organism and analyzed the changing aspects of closed to open forms of rRNA gene chromatin during cell cycle arrest, the arrangement of RNA polymerase-I (RNAPI) on the open genes, the presence of RNAPI transcription-factors, transcription and rRNA maturation. The rRNA gene chromatin structure was analyzed by psoralen crosslinking and the distribution of RNAPI was investigated by chromatin endogenous cleavage. In HU arrested cells nearly all rRNA genes were in the open form of chromatin, but only a portion of them was engaged with RNAPI. Analyses by chromatin immuno-precipitation confirmed that the overall formation of transcription pre-initiation complexes remained unchanged, suggesting that the onset of rRNA gene activation was not significantly affected by HU. Moreover, the in vitro transcription run-on assay indicated that RNAPI retained most of its transcription elongation activity. However, in HU treated cells, we found that: (1) RNAPI accumulated next to the 5'-end of rRNA genes; (2) considerably less rRNA filaments were observed in electron micrographs of rDNA transcription units; and (3) rRNA maturation was compromised. It is established that HU inhibition of ribonucleotide reductase holds back DNA replication. This study indicates a hitherto unexplored cellular response to HU, namely altered rRNA synthesis, which could participate to hamper cell division., (Copyright © 2019 Elsevier B.V. All rights reserved.)

Published

2019

50. Pif1-Family Helicases Support Fork Convergence during DNA Replication Termination in Eukaryotes.

Author

Deegan TD, Baxter J, Ortiz Bazán MÁ, Yeeles JTP, and Labib KPM

Subjects

DNA Topoisomerases genetics, Escherichia coli genetics, Eukaryota genetics, Genomic Instability, Plasmids genetics, DNA Helicases genetics, DNA Replication genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics

Abstract

The convergence of two DNA replication forks creates unique problems during DNA replication termination. In E. coli and SV40, the release of torsional strain by type II topoisomerases is critical for converging replisomes to complete DNA synthesis, but the pathways that mediate fork convergence in eukaryotes are unknown. We studied the convergence of reconstituted yeast replication forks that include all core replisome components and both type I and type II topoisomerases. We found that most converging forks stall at a very late stage, indicating a role for additional factors. We showed that the Pif1 and Rrm3 DNA helicases promote efficient fork convergence and completion of DNA synthesis, even in the absence of type II topoisomerase. Furthermore, Rrm3 and Pif1 are also important for termination of plasmid DNA replication in vivo. These findings identify a eukaryotic pathway for DNA replication termination that is distinct from previously characterized prokaryotic mechanisms., (Copyright © 2019 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2019