| 1. |
- Tran, Phong, 1987-
(author)
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Pathology of dNTP dysregulation
- 2020
-
Doctoral thesis (other academic/artistic)abstract
- Deoxyribonucleoside triphosphates (dNTPs) are precursors for DNA replication and repair. Mammalian cells have two distinct biosynthesis pathways to supply dNTPs: de novo and salvage pathways. These pathways are intimately coordinated to maintain optimal dNTP concentrations throughout different phases of the cell cycle, and perturbations in the production of dNTPs could lead to increased, decreased, or imbalanced dNTP pools. In yeasts, changes in both the level and balance of dNTPs increase mutation rates and genome instability. In mammals, elevated mutation rates and genome instability predispose to numerous diseases, including cancer. However, the correlation of dNTP changes with pathology has not been well established in mammals. In this thesis, I present how we addressed this issue using three separate mouse models – one with an increased dNTP pool, one with a decreased dNTP pool, and one with an imbalanced dNTP pool. To modulate dNTP levels in the mice, we deleted or mutated either sterile alpha motif and histidine-aspartic domain containing protein 1 (SAMHD1) or ribonucleotide reductase (RNR) proteins, which are involved in the salvage and de novo pathways, respectively. In the first model, mouse embryos without the SAMHD1 gene showed a slight increase in dNTP levels. A similar increase in dNTPs conferred moderately elevated mutation rates in cultured cancer cells. In the second model, we created a mouse strain carrying a modified allosteric specificity site in a subunit of RNR. Embryos with a heterozygous mutation had a mildly imbalanced dNTP pool. Heterozygous mutant mice showed a shorter lifespan and increased incidence and earlier onset of cancer. In the third model, the de novo dNTP production was inactivated in cardiac and skeletal muscles through the deletion of a gene encoding RNR. The hearts of knockout pups showed significant depletion of dNTPs, leading to aberrant DNA replication. In addition, knockout pups developed anatomic and histologic cardiac abnormalities and impaired cardiac conduction systems. As a result, they died between two and four weeks after birth. Taken together, our studies provide the first empirical evidence that both the de novo and salvage pathways are essential to keeping the dNTP concentration at an optimal range to prevent mutagenesis, carcinogenesis, and mortality.
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| 2. |
- Batté, Amandine, et al.
(author)
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Chl1 helicase controls replication fork progression by regulating dNTP pools
- 2022
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In: Life Science Alliance. - : Life Science Alliance, LLC. - 2575-1077. ; 5:4
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Journal article (peer-reviewed)abstract
- Eukaryotic cells have evolved a replication stress response that helps to overcome stalled/collapsed replication forks and ensure proper DNA replication. The replication checkpoint protein Mrc1 plays important roles in these processes, although its functional interactions are not fully understood. Here, we show that MRC1 negatively interacts with CHL1, which encodes the helicase protein Chl1, suggesting distinct roles for these factors during the replication stress response. Indeed, whereas Mrc1 is known to facilitate the restart of stalled replication forks, we uncovered that Chl1 controls replication fork rate under replication stress conditions. Chl1 loss leads to increased RNR1 gene expression and dNTP levels at the onset of S phase likely without activating the DNA damage response. This in turn impairs the formation of RPA-coated ssDNA and subsequent checkpoint activation. Thus, the Chl1 helicase affects RPA-dependent checkpoint activation in response to replication fork arrest by ensuring proper intracellular dNTP levels, thereby controlling replication fork progression under replication stress conditions.
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| 3. |
- Buckland, Robert, 1976-
(author)
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DNA precursor asymmetries, Mismatch Repair and their effect on mutation specificity
- 2015
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Doctoral thesis (other academic/artistic)abstract
- In order to build any structure, a good supply of materials, accurate workers and quality control are needed. This is even the case when constructing DNA, the so-called “Code of Life.” For a species to continue to exist, this DNA code must be copied with incredibly high accuracy when each and every cell replicates. In fact, just one mistake in the 12 million bases that comprise the genome of budding yeast, Saccharomyces cerevisiae, can be fatal. DNA is composed of a double strand helix made up of just four different bases repeated millions of times. The building blocks of DNA are the deoxyribonucleotides (dNTPs); dCTP, dTTP, dATP and dGTP. Their production and balance are carefully controlled within each cell, largely by the key enzyme Ribonucleotide Reductase (RNR). Here, we studied how the enzymes that copy DNA, the replicative polymerases α, δ and ε, cope with the effects of an altered dNTP pool balance. An introduced mutation in the allosteric specificity site of RNR in a strain of S. cerevisiae, rnr1-Y285A, leads to elevated dCTP and dTTP levels and has been shown to have a 14-fold increase in mutation rate compared to wild type. To ascertain the full effects of the dNTP pool imbalance upon the replicative polymerases, we disabled one of the major quality control systems in a cell that corrects replication errors, the post-replicative Mismatch Repair system. Using both the CAN1 reporter assay and whole genome sequencing, we found that, despite inherent differences between the polymerases, their replication fidelity was affected very similarly by this dNTP pool imbalance. Hence, the high dCTP and dTTP forced Pol ε and Pol α/δ to make the same mistakes. In addition, the mismatch repair machinery was found to correct replication errors driven by this dNTP pool imbalance with highly variable efficiencies. Another mechanism to protect cells from DNA damage during replication is a checkpoint that can be activated to delay the cell cycle and activate repair mechanisms. In yeast, Mec1 and Rad53 (human ATR and Chk1/Chk2) are two key S-phase checkpoint proteins. They are essential as they are also required for normal DNA replication and dNTP pool regulation. However the reason why they are essential is not well understood. We investigated this by mutating RAD53 and analyzing dNTP pools and gene interactions. We show that Rad53 is essential in S-phase due to its role in regulating basal dNTP levels by action in the Dun1 pathway that regulates RNR and Rad53’s compensatory kinase function if dNTP levels are perturbed.In conclusion we present further evidence of the importance of dNTP pools in the maintenance of genome integrity and shed more light on the complex regulation of dNTP levels.
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| 4. |
- Cerritelli, Susana M, et al.
(author)
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High density of unrepaired genomic ribonucleotides leads to Topoisomerase 1-mediated severe growth defects in absence of ribonucleotide reductase
- 2020
-
In: Nucleic Acids Research. - : Oxford Academic. - 0305-1048 .- 1362-4962. ; 48:8, s. 4274-4297
-
Journal article (peer-reviewed)abstract
- Cellular levels of ribonucleoside triphosphates (rNTPs) are much higher than those of deoxyribonucleoside triphosphates (dNTPs), thereby influencing the frequency of incorporation of ribonucleoside monophosphates (rNMPs) by DNA polymerases (Pol) into DNA. RNase H2-initiated ribonucleotide excision repair (RER) efficiently removes single rNMPs in genomic DNA. However, processing of rNMPs by Topoisomerase 1 (Top1) in absence of RER induces mutations and genome instability. Here, we greatly increased the abundance of genomic rNMPs in Saccharomyces cerevisiae by depleting Rnr1, the major subunit of ribonucleotide reductase, which converts ribonucleotides to deoxyribonucleotides. We found that in strains that are depleted of Rnr1, RER-deficient, and harbor an rNTP-permissive replicative Pol mutant, excessive accumulation of single genomic rNMPs severely compromised growth, but this was reversed in absence of Top1. Thus, under Rnr1 depletion, limited dNTP pools slow DNA synthesis by replicative Pols and provoke the incorporation of high levels of rNMPs in genomic DNA. If a threshold of single genomic rNMPs is exceeded in absence of RER and presence of limited dNTP pools, Top1-mediated genome instability leads to severe growth defects. Finally, we provide evidence showing that accumulation of RNA/DNA hybrids in absence of RNase H1 and RNase H2 leads to cell lethality under Rnr1 depletion.
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| 5. |
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| 6. |
- Coquel, F., et al.
(author)
-
SAMHD1 agit sur les fourches de réplication bloquées pour empêcher l’induction d’interféron : [SAMHD1 acts at stalled replication forks to prevent interferon induction]
- 2020
-
In: Comptes rendus. Biologies. - : Académie des Sciences. - 1631-0691 .- 1768-3238. ; 343:1, s. 9-21
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Journal article (peer-reviewed)abstract
- DNA replication is an extremely complex process, involving thousands of replication forks progressing along chromosomes. These forks are frequently slowed down or stopped by various obstacles, such as secondary DNA structures, chromatin-acting proteins or a lack of nucleotides. This slowing down, known as replicative stress, plays a central role in tumour development. Complex processes, which are not yet fully understood, are set up to respond to this stress. Certain nucleases, such as MRE11 and DNA2, degrade the neo-replicated DNA at the level of blocked forks, allowing the replication to restart. The interferon pathway is a defense mechanism against pathogens that detects the presence of foreign nucleic acids in the cytoplasm and activates the innate immune response. DNA fragments resulting from genomic DNA metabolism (repair, retrotransposition) can diffuse into the cytoplasm and activate this pathway. A pathological manifestation of this process is the Aicardi-Goutieres syndrome, a rare disease characterized by chronic inflammation leading to neurodegenerative and developmental problems. In this encephalopathy, it has been suggested that DNA replication may generate cytosolic DNA fragments, but the mechanisms involved have not been characterized. SAMHD1 is frequently mutated in the Aicardi-Goutieres syndrome as well as in some cancers, but its role in the etiology of these diseases was largely unknown. We show that cytosolic DNA accumulates in SAMHD1-deficient cells, particularly in the presence of replicative stress, activating the interferon response. SAMHD1 is important for DNA replication under normal conditions and for the processing of stopped forks, independent of its dNTPase activity. In addition, SAMHD1 stimulates the exonuclease activity of MRE11 in vitro. When SAMHD1 is absent, degradation of neosynthesized DNA is inhibited, which prevents activation of the replication checkpoint and leads to failure to restart the replication forks. Resection of the replication forks is performed by an alternative mechanism which releases DNA fragments into the cytosol, activating the interferon response. The results obtained show, for the first time, a direct link between the response to replication stress and the production of interferons. These results have important implications for our understanding of the Aicardi-Goutieres syndrome and cancers related to SAMHD1. For example, we have shown that MRE11 and RECQ1 are responsible for the production of DNA fragments that trigger the inflammatory response in cells deficient for SAMHD1. We can therefore imagine that blocking the activity of these enzymes could decrease the production of DNA fragments and, ultimately, the activation of innate immunity in these cells. In addition, the interferon pathway plays an essential role in the therapeutic efficacy of irradiation and certain chemotherapeutic agents such as oxaliplatin. Modulating this response could therefore be of much wider interest in anti-tumour therapy.
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| 7. |
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| 8. |
- Davenne, Tamara, et al.
(author)
-
SAMHD1 Limits the Efficacy of Forodesine in Leukemia by Protecting Cells against the Cytotoxicity of dGTP.
- 2020
-
In: Cell Reports. - : Elsevier. - 2211-1247. ; 31:6
-
Journal article (peer-reviewed)abstract
- The anti-leukemia agent forodesine causes cytotoxic overload of intracellular deoxyguanosine triphosphate (dGTP) but is efficacious only in a subset of patients. We report that SAMHD1, a phosphohydrolase degrading deoxyribonucleoside triphosphate (dNTP), protects cells against the effects of dNTP imbalances. SAMHD1-deficient cells induce intrinsic apoptosis upon provision of deoxyribonucleosides, particularly deoxyguanosine (dG). Moreover, dG and forodesine act synergistically to kill cells lacking SAMHD1. Using mass cytometry, we find that these compounds kill SAMHD1-deficient malignant cells in patients with chronic lymphocytic leukemia (CLL). Normal cells and CLL cells from patients without SAMHD1 mutation are unaffected. We therefore propose to use forodesine as a precision medicine for leukemia, stratifying patients by SAMHD1 genotype or expression.
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| 9. |
- Dmowski, Michal, et al.
(author)
-
Impairment of the non-catalytic subunit Dpb2 of DNA Pol ɛ results in increased involvement of Pol δ on the leading strand
- 2023
-
In: DNA Repair. - : Elsevier. - 1568-7864 .- 1568-7856. ; 129
-
Journal article (peer-reviewed)abstract
- The generally accepted model assumes that leading strand synthesis is performed by Pol ε, while lagging-strand synthesis is catalyzed by Pol δ. Pol ε has been shown to target the leading strand by interacting with the CMG helicase [Cdc45 Mcm2–7 GINS(Psf1–3, Sld5)]. Proper functioning of the CMG-Pol ɛ, the helicase-polymerase complex is essential for its progression and the fidelity of DNA replication. Dpb2p, the essential non-catalytic subunit of Pol ε plays a key role in maintaining the correct architecture of the replisome by acting as a link between Pol ε and the CMG complex. Using a temperature-sensitive dpb2–100 mutant previously isolated in our laboratory, and a genetic system which takes advantage of a distinct mutational signature of the Pol δ-L612M variant which allows detection of the involvement of Pol δ in the replication of particular DNA strands we show that in yeast cells with an impaired Dpb2 subunit, the contribution of Pol δ to the replication of the leading strand is significantly increased.
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| 10. |
- Dmowski, Michal, et al.
(author)
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Increased contribution of DNA polymerase delta to the leading strand replication in yeast with an impaired CMG helicase complex
- 2022
-
In: DNA Repair. - : Elsevier. - 1568-7864 .- 1568-7856. ; 110
-
Journal article (peer-reviewed)abstract
- DNA replication is performed by replisome proteins, which are highly conserved from yeast to humans. The CMG [Cdc45-Mcm2–7-GINS(Psf1–3, Sld5)] helicase unwinds the double helix to separate the leading and lagging DNA strands, which are replicated by the specialized DNA polymerases epsilon (Pol ε) and delta (Pol δ), respectively. This division of labor was confirmed by both genetic analyses and in vitro studies. Exceptions from this rule were described mainly in cells with impaired catalytic polymerase ε subunit. The central role in the recruitment and establishment of Pol ε on the leading strand is played by the CMG complex assembled on DNA during replication initiation. In this work we analyzed the consequences of impaired functioning of the CMG complex for the division labor between DNA polymerases on the two replicating strands. We showed in vitro that the GINSPsf1–1 complex poorly bound the Psf3 subunit. In vivo, we observed increased rates of L612M Pol δ-specific mutations during replication of the leading DNA strand in psf1–1 cells. These findings indicated that defective functioning of GINS impaired leading strand replication by Pol ε and necessitated involvement of Pol δ in the synthesis on this strand with a possible impact on the distribution of mutations and genomic stability. These are the first results to imply that the division of labor between the two main replicases can be severely influenced by a defective nonpolymerase subunit of the replisome.
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| 11. |
- Forey, Romain, et al.
(author)
-
Mec1 Is Activated at the Onset of Normal S Phase by Low-dNTP Pools Impeding DNA Replication
- 2020
-
In: Molecular Cell. - : Elsevier. - 1097-2765 .- 1097-4164. ; 78:3, s. 496-410.e4
-
Journal article (peer-reviewed)abstract
- The Mec1 and Rad53 kinases play a central role during acute replication stress in budding yeast. They are also essential for viability in normal growth conditions, but the signal that activates the Mec1-Rad53 pathway in the absence of exogenous insults is currently unknown. Here, we show that this pathway is active at the onset of normal S phase because deoxyribonucleotide triphosphate (dNTP) levels present in G1 phase may not be sufficient to support processive DNA synthesis and impede DNA replication. This activation can be suppressed experimentally by increasing dNTP levels in G1 phase. Moreover, we show that unchallenged cells entering S phase in the absence of Rad53 undergo irreversible fork collapse and mitotic catastrophe. Together, these data indicate that cells use suboptimal dNTP pools to detect the onset of DNA replication and activate the Mec1-Rad53 pathway, which in turn maintains functional forks and triggers dNTP synthesis, allowing the completion of DNA replication.
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| 12. |
- Garbacz, Marta A., et al.
(author)
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The absence of the catalytic domains of Saccharomyces cerevisiae DNA polymerase ϵ strongly reduces DNA replication fidelity
- 2019
-
In: Nucleic Acids Research. - : Oxford University Press. - 0305-1048 .- 1362-4962. ; 47:8, s. 3986-3995
-
Journal article (peer-reviewed)abstract
- The four B-family DNA polymerases α, δ, ϵ and ζ cooperate to accurately replicate the eukaryotic nuclear genome. Here, we report that a Saccharomyces cerevisiae strain encoding the pol2-16 mutation that lacks Pol ϵ's polymerase and exonuclease activities has increased dNTP concentrations and an increased mutation rate at the CAN1 locus compared to wild type yeast. About half of this mutagenesis disappears upon deleting the REV3 gene encoding the catalytic subunit of Pol ζ. The remaining, still strong, mutator phenotype is synergistically elevated in an msh6Δ strain and has a mutation spectrum characteristic of mistakes made by Pol δ. The results support a model wherein slow-moving replication forks caused by the lack of Pol ϵ's catalytic domains result in greater involvement of mutagenic DNA synthesis by Pol ζ as well as diminished proofreading by Pol δ during replication.
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| 13. |
- Kumar, Dinesh, 1981-
(author)
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dNTPs : the alphabet of life
- 2010
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Doctoral thesis (other academic/artistic)abstract
- From microscopic bacteria to the giant whale, every single living organism on Earth uses the same language of life: DNA. Deoxyribonucleoside triphosphates––dNTPs (dATP, dTTP, dGTP, and dCTP)––are the building blocks of DNA and are therefore the “alphabet of life”. A balanced supply of dNTPs is essential for integral DNA transactions such as faithful genome duplication and repair. The enzyme ribonucleotide reductase (RNR) not only synthesizes all four dNTPs but also primarily maintains the crucial individual concentration of each dNTP in a cell. In this thesis we investigated what happens if the crucial balanced supply of dNTPs is disrupted, addressing whether a cell has a mechanism to detect imbalanced dNTP pools and whether all pool imbalances are equally mutagenic. To address these questions, we introduced single amino acid substitutions into loop 2 of the allosteric specificity site of Saccharomyces cerevisiae RNR and obtained a collection of yeast strains with different but defined dNTP pool imbalances. These results directly confirmed that the loop 2 is the structural link between the substrate specificity and effector binding sites of RNR. We were surprised to observe that mutagenesis was enhanced even in a strain with mildly imbalanced dNTP pools, despite the availability of the two major replication error correction mechanisms: proofreading and mismatch repair. However, the mutagenic potential of different dNTP pool imbalances did not directly correlate with their severity, and the locations of the mutations in a strain with elevated dTTP and dCTP were completely different from those in a strain with elevated dATP and dGTP. We then investigated, whether dNTP pool imbalances interfere with cell cycle progression and if they are detected by the S-phase checkpoint, a genome surveillance mechanism activated in response to DNA damage or replication blocks. The S-phase checkpoint was activated by the depletion of one or more dNTPs. In contrast, when none of the dNTP pools was limiting for DNA replication, even extreme and mutagenic dNTP pool imbalances did not activate the S-phase checkpoint and did not interfere with the cell cycle progression. We also observed an interesting mutational strand bias in one of the mutant rnr1 strains suggesting that the S-phase checkpoint may selectively prevent formation of replication errors during leading strand replication. We further used these strains to study the mechanisms by which dNTP pool imbalances induce genome instability. In addition, we discovered that a high dNTP concentration allows replicative DNA polymerases to bypass certain DNA lesions, which are difficult to bypass at normal dNTP concentrations. Our results broaden the role of dNTPs beyond ‘dNTPs as the building blocks’ and suggest that dNTPs are not only the building blocks of DNA but also that their concentrations in a cell have regulatory implications for maintaining genomic integrity. This is important as all cancers arise as a result of some kind of genomic abnormality.
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| 14. |
- Nicholls, Thomas J., et al.
(author)
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Dinucleotide Degradation by REXO2 Maintains Promoter Specificity in Mammalian Mitochondria
- 2019
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In: Molecular Cell. - : Elsevier BV. - 1097-2765 .- 1097-4164. ; 76:5
-
Journal article (peer-reviewed)abstract
- Oligoribonucleases are conserved enzymes that degrade short RNA molecules of up to 5 nt in length and are assumed to constitute the final stage of RNA turnover. Here we demonstrate that REXO2 is a specialized dinucleotide-degrading enzyme that shows no preference between RNA and DNA dinucleotide substrates. A heart- and skeletal-muscle-specific knockout mouse displays elevated dinucleotide levels and alterations in gene expression patterns indicative of aberrant dinucleotide-primed transcription initiation. We find that dinucleotides act as potent stimulators of mitochondrial transcription initiation in vitro. Our data demonstrate that increased levels of dinucleotides can be used to initiate transcription, leading to an increase in transcription levels from both mitochondrial promoters and other, nonspecific sequence elements in mitochondrial DNA. Efficient RNA turnover by REXO2 is thus required to maintain promoter specificity and proper regulation of transcription in mammalian mitochondria.
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| 15. |
- Ranjbarian, Farahnaz, et al.
(author)
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Isocratic HPLC analysis for the simultaneous determination of dNTPs, rNTPs and ADP in biological samples
- 2022
-
In: Nucleic Acids Research. - : Oxford University Press. - 0305-1048 .- 1362-4962. ; 50:3
-
Journal article (peer-reviewed)abstract
- Information about the cellular concentrations of deoxyribonucleoside triphosphates (dNTPs) is instrumental for mechanistic studies of DNA replication and for understanding diseases caused by defects in dNTP metabolism. The dNTPs are measured by methods based on either HPLC or DNA polymerization. An advantage with the HPLC-based techniques is that the parallel analysis of ribonucleoside triphosphates (rNTPs) can serve as an internal quality control of nucleotide integrity and extraction efficiency. We have developed a Freon-free trichloroacetic acid-based method to extract cellular nucleotides and an isocratic reverse phase HPLC-based technique that is able to separate dNTPs, rNTPs and ADP in a single run. The ability to measure the ADP levels improves the control of nucleotide integrity, and the use of an isocratic elution overcomes the shifting baseline problems in previously developed gradient-based reversed phase protocols for simultaneously measuring dNTPs and rNTPs. An optional DNA-polymerase-dependent step is used for confirmation that the dNTP peaks do not overlap with other components of the extracts, further increasing the reliability of the analysis. The method is compatible with a wide range of biological samples and has a sensitivity better than other UV-based HPLC protocols, closely matching that of mass spectrometry-based detection.
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| 16. |
- Rentoft, Matilda, et al.
(author)
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A geographically matched control population efficiently limits the number of candidate disease-causing variants in an unbiased whole-genome analysis
- 2019
-
In: PLoS ONE. - : Public Library of Science (PLoS). - 1932-6203 .- 1932-6203. ; 14:3
-
Journal article (peer-reviewed)abstract
- Whole-genome sequencing is a promising approach for human autosomal dominant disease studies. However, the vast number of genetic variants observed by this method constitutes a challenge when trying to identify the causal variants. This is often handled by restricting disease studies to the most damaging variants, e. g. those found in coding regions, and overlooking the remaining genetic variation. Such a biased approach explains in part why the genetic causes of many families with dominantly inherited diseases, in spite of being included in whole-genome sequencing studies, are left unsolved today. Here we explore the use of a geographically matched control population to minimize the number of candidate disease-causing variants without excluding variants based on assumptions on genomic position or functional predictions. To exemplify the benefit of the geographically matched control population we apply a typical disease variant filtering strategy in a family with an autosomal dominant form of colorectal cancer. With the use of the geographically matched control population we end up with 26 candidate variants genome wide. This is in contrast to the tens of thousands of candidates left when only making use of available public variant datasets. The effect of the local control population is dual, it (1) reduces the total number of candidate variants shared between affected individuals, and more importantly (2) increases the rate by which the number of candidate variants are reduced as additional affected family members are included in the filtering strategy. We demonstrate that the application of a geographically matched control population effectively limits the number of candidate disease-causing variants and may provide the means by which variants suitable for functional studies are identified genome wide.
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| 17. |
- Schmidt, Tobias T, et al.
(author)
-
Inactivation of folylpolyglutamate synthetase Met7 results in genome instability driven by an increased dUTP/dTTP ratio
- 2020
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In: Nucleic Acids Research. - : Oxford University Press. - 0305-1048 .- 1362-4962. ; 48:1, s. 264-277
-
Journal article (peer-reviewed)abstract
- The accumulation of mutations is frequently associated with alterations in gene function leading to the onset of diseases, including cancer. Aiming to find novel genes that contribute to the stability of the genome, we screened the Saccharomyces cerevisiae deletion collection for increased mutator phenotypes. Among the identified genes, we discovered MET7, which encodes folylpolyglutamate synthetase (FPGS), an enzyme that facilitates several folate-dependent reactions including the synthesis of purines, thymidylate (dTMP) and DNA methylation. Here, we found that Met7-deficient strains show elevated mutation rates, but also increased levels of endogenous DNA damage resulting in gross chromosomal rearrangements (GCRs). Quantification of deoxyribonucleotide (dNTP) pools in cell extracts from met7Δ mutant revealed reductions in dTTP and dGTP that cause a constitutively active DNA damage checkpoint. In addition, we found that the absence of Met7 leads to dUTP accumulation, at levels that allowed its detection in yeast extracts for the first time. Consequently, a high dUTP/dTTP ratio promotes uracil incorporation into DNA, followed by futile repair cycles that compromise both mitochondrial and nuclear DNA integrity. In summary, this work highlights the importance of folate polyglutamylation in the maintenance of nucleotide homeostasis and genome stability.
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| 18. |
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| 19. |
- Sharma, Sushma, et al.
(author)
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Quantitative analysis of nucleoside triphosphate pools in mouse muscle using hydrophilic interaction liquid chromatography coupled with tandem mass spectrometry detection
- 2023
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In: Mitochondrial DNA. - New York : Humana Press. - 9781071629215 - 9781071629222 ; , s. 267-280
-
Book chapter (peer-reviewed)abstract
- Defects in deoxyribonucleoside triphosphate (dNTP) metabolism are associated with a number of mitochondrial DNA (mtDNA) depletion syndromes (MDS). These disorders affect the muscles, liver, and brain, and the concentrations of dNTPs in these tissues are already normally low and are, therefore, difficult to measure. Thus, information about the concentrations of dNTPs in tissues of healthy animals and animals with MDS are important for mechanistic studies of mtDNA replication, analysis of disease progression, and the development of therapeutic interventions. Here, we present a sensitive method for the simultaneous analysis of all four dNTPs as well as all four ribonucleoside triphosphates (NTPs) in mouse muscles using hydrophilic interaction liquid chromatography coupled with triple quadrupole mass spectrometry. The simultaneous detection of NTPs allows them to be used as internal standards for the normalization of dNTP concentrations. The method can be applied for measuring dNTP and NTP pools in other tissues and organisms.
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| 20. |
- Tran, Phong, et al.
(author)
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De novo dNTP production is essential for normal postnatal murine heart development
- 2019
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In: Journal of Biological Chemistry. - : American Society for Biochemistry and Molecular Biology. - 0021-9258 .- 1083-351X. ; 394:44, s. 15889-15897
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Journal article (peer-reviewed)abstract
- The building blocks of DNA, dNTPs, can be produced de novo or can be salvaged from deoxyribonucleosides. However, to what extent the absence of de novo dNTP production can be compensated for by the salvage pathway is unknown. Here, we eliminated de novo dNTP synthesis in the mouse heart and skeletal muscle by inactivating ribonucleotide reductase (RNR), a key enzyme for the de novo production of dNTPs, at embryonic day 13. All other tissues had normal de novo dNTP synthesis and theoretically could supply heart and skeletal muscle with deoxyribonucleosides needed for dNTP production by salvage. We observed that the dNTP and NTP pools in wild-type postnatal hearts are unexpectedly asymmetric, with unusually high dGTP and GTP levels compared with those in whole mouse embryos or murine cell cultures. We found that RNR inactivation in heart led to strongly decreased dGTP and increased dCTP, dTTP, and dATP pools; aberrant DNA replication; defective expression of muscle-specific proteins; progressive heart abnormalities; disturbance of the cardiac conduction system; and lethality between the second and fourth weeks after birth. We conclude that dNTP salvage cannot substitute for de novo dNTP synthesis in the heart and that cardiomyocytes and myocytes initiate DNA replication despite an inadequate dNTP supply. We discuss the possible reasons for the observed asymmetry in dNTP and NTP pools in wildtype hearts.
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| 21. |
- Tran, Phong, et al.
(author)
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Imbalanced dNTP pools induce mutator and cancer phenotypes in mice
-
Other publication (other academic/artistic)abstract
- The high accuracy of DNA replication is achieved through the nucleotide selectivity of DNA polymerases, polymerase proofreading, and the mismatch repair (MMR) system that act in series. While defects in proofreading and MMR are strongly associated with the development of cancers, decreased nucleotide selectivity due to mutations in replicative DNA polymerases is an uncommon driver of cancer development. Because nucleotide selectivity can also be decreased by imbalanced dNTP pools, we investigated to what extent imbalanced dNTP pools can induce cancers. To this end we developed a mouse model with a mutation in the allosteric specificity site of ribonucleotide reductase, which is responsible for the balanced production of dNTPs. These mice had ~2-fold increased dCTP and dTTP levels and normal dATP and dGTP levels. Despite this mild dNTP pool imbalance, mutant mice had a higher incidence and an earlier onset of cancers, and these were different from the cancers that developed in wild-type controls. Because dNTP pool imbalances can be caused by defects in a plethora of genes, we propose that decreased nucleotide selectivity might be a major factor contributing to the development of spontaneous cancers.
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| 22. |
- Tsaponina, Olga, 1978-
(author)
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Regulation of ribonucleotide reductase and the role of dNTP pools in genomic stability in yeast Saccharomyces cerevisiae
- 2011
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Doctoral thesis (other academic/artistic)abstract
- Every living organism is programmed to reproduce and to pass genetic information to descendants. The information has to be carefully copied and accurately transferred to the next generation. Therefore organisms have developed the network of conserved mechanisms to survey the protection and precise transfer of the genetic information. Such mechanisms are called checkpoints and they monitor the correct execution of different cell programs. The DNA damage and the replication blocks are surveyed by the conserved Mec1-Rad53 (human ATM/ATR and Chk2, respectively) protein kinase cascade. Mec1 and Rad53 are essential for survival and when activated orchestrate the multiple cellular responses, including the activation of the ribonucleotide reductase (RNR), to the genotoxic stress. RNR is an enzyme producing all four dNTPs - the building blocks of the DNA - and is instrumental for the maintenance both proper concentration and balance of each of dNTPs. The appropriate concentration of the dNTPs should be strictly regulated since inadequate dNTP production can impede many cellular processes and lead to higher mutation rates and genome instability. Hence RNR activity is regulated at many levels, including allosteric and transcriptional regulation and the inhibition at protein level. In our research, we addressed the question of the transcriptional regulation of RNR and the consequences of dNTP malproduction in the terms of the genomic stability. In yeast S. cerevisiae, four genes encode RNR: 2 genes encode a large subunit (RNR1 and RNR3) and 2 genes encode a small subunit (RNR2 and RNR4). All 4 genes are DNA-damage inducible: transcription of RNR2, RNR3 and RNR4 is regulated via Mec1-Rad53-Dun1 pathway by targeting the transcriptional repressor Crt1 (Rfx1) for degradation; on the contrary, RNR1 gene promoter does not contain Crt1-binding sites and is not regulated through the Mec1-Rad53-Dun1 pathway. Instead, we show that intrastrand cross (X)-link recognition protein (Ixr1) is required for the proper transcription of the RNR1 gene and maintenance of the dNTP pools both during unperturbed cell cycle and after the DNA damage. Thus, we identify the novel regulator of the RNR1 transcription. Next, we show that the depletion of dNTP pools negatively affects genome stability in the hypomorphic mec1 mutants: the hyper-recombination phenotype in those mutants correlates with low dNTP levels. By introducing even lower dNTP levels the hyper-recombination increased even further and conversely all the hyper-recombination phenotypes were suppressed by artificial elevation of dNTP levels. In conclusion, we present Ixr1 as a novel regulator of the RNR activity and provide the evidence of role of dNTP concentration in the genome stability.
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| 23. |
- Wanrooij, Paulina H., et al.
(author)
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Elimination of rNMPs from mitochondrial DNA has no effect on its stability
- 2020
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In: Proceedings of the National Academy of Sciences of the United States of America. - : Proceedings of the National Academy of Sciences. - 0027-8424 .- 1091-6490. ; 117:25, s. 14306-14313
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Journal article (peer-reviewed)abstract
- Ribonucleotides (rNMPs) incorporated in the nuclear genome are a well-established threat to genome stability and can result in DNA strand breaks when not removed in a timely manner. However, the presence of a certain level of rNMPs is tolerated in mitochondrial DNA (mtDNA) although aberrant mtDNA rNMP content has been identified in disease models. We investigated the effect of incorporated rNMPs on mtDNA stability over the mouse life span and found that the mtDNA rNMP content increased during early life. The rNMP content of mtDNA varied greatly across different tissues and was defined by the rNTP/dNTP ratio of the tissue. Accordingly, mtDNA rNMPs were nearly absent in SAMHD1(-/-) mice that have increased dNTP pools. The near absence of rNMPs did not, however, appreciably affect mtDNA copy number or the levels of mtDNA molecules with deletions or strand breaks in aged animals near the end of their life span. The physiological rNMP load therefore does not contribute to the progressive loss of mtDNA quality that occurs as mice age.
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| 24. |
- Wanrooij, Paulina H., et al.
(author)
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NME6: ribonucleotide salvage sustains mitochondrial transcription
- 2023
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In: EMBO Journal. - : John Wiley & Sons. - 0261-4189 .- 1460-2075. ; 42:18
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Journal article (peer-reviewed)abstract
- The building blocks for RNA and DNA are made in the cytosol, meaning mitochondria depend on the import and salvage of ribonucleoside triphosphates (rNTPs) and deoxyribonucleoside triphosphates (dNTPs) for the synthesis of their own genetic material. While extensive research has focused on mitochondrial dNTP homeostasis due to its defects being associated with various mitochondrial DNA (mtDNA) depletion and deletion syndromes, the investigation of mitochondrial rNTP homeostasis has received relatively little attention. In this issue of the EMBO Journal, Grotehans et al provide compelling evidence of a major role for NME6, a mitochondrial nucleoside diphosphate kinase, in the conversion of pyrimidine ribonucleoside diphosphates into the corresponding triphosphates. These data also suggest a significant physiological role for NME6, as its absence results in the depletion of mitochondrial transcripts and destabilization of the electron transport chain (Grotehans et al, 2023).
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| 25. |
- Wanrooij, Paulina H., et al.
(author)
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Ribonucleotides in mitochondrial DNA
- 2019
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In: FEBS Letters. - : John Wiley & Sons. - 0014-5793 .- 1873-3468. ; 593:13, s. 1554-1565
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Research review (peer-reviewed)abstract
- The incorporation of ribonucleotides (rNMPs) into DNA during genome replication has gained substantial attention in recent years and has been shown to be a significant source of genomic instability. Studies in yeast and mammals have shown that the two genomes, the nuclear DNA (nDNA) and the mitochondrial DNA (mtDNA), differ with regard to their rNMP content. This is largely due to differences in rNMP repair - whereas rNMPs are efficiently removed from the nuclear genome, mitochondria lack robust mechanisms for removal of single rNMPs incorporated during DNA replication. In this minireview, we describe the processes that determine the frequency of rNMPs in the mitochondrial genome and summarise recent findings regarding the effect of incorporated rNMPs on mtDNA stability and function.
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| 26. |
- Wiberg, Jörgen, 1982-
(author)
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Mechanisms controlling DNA damage survival and mutation rates in budding yeast
- 2012
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Doctoral thesis (other academic/artistic)abstract
- All living organisms are made of cells, within which genetic information is stored on long strands of deoxyribonucleic acid (DNA). The DNA encodes thousands of different genes and provides the blueprint for all of the structures and activities occurring within the cell. The building blocks of DNA are the four deoxyribonucleotides, dATP, dGTP, dTTP, and dCTP, which are collectively referred to as dNTPs. The key enzyme in the production of dNTPs is ribonucleotide reductase (RNR). In the budding yeast Saccharomyces cerevisiae, the concentrations of the individual dNTPs are not equal and it is primarily RNR that maintains this balance. Maintenance of the dNTP pool balance is critical for accurate DNA replication and DNA repair since elevated and/or imbalanced dNTP concentrations increase the mutation rate and can ultimately lead to genomic instability and cancer. In response to DNA damage, the overall dNTP concentration in S. cerevisiae increases. Cell survival rates increase as a result of the elevated concentration of dNTPs, but the cells also suffer from a concomitant increase in mutation rates. When the replication machinery encounters DNA damage that it cannot bypass, the replication fork stalls and recruits specialized translesion synthesis (TLS) polymerases that bypass the damage so that replication can continue. We hypothesized that elevated dNTP levels in response to DNA damage may allow the TLS polymerases to more efficiently bypass DNA damage. To explore this possibility, we deleted all known TLS polymerases in a yeast strain in which we could artificially increase the dNTP concentrations. Surprisingly, even though all TLS polymerases had been deleted, elevated dNTP concentrations led to increased cell survival after DNA damage. These results suggest that replicative DNA polymerases may be involved in the bypass of certain DNA lesions under conditions of elevated dNTPs. We confirmed this hypothesis in vitro by demonstrating that high dNTP concentrations result in an increased efficiency in the bypass of certain DNA lesions by DNA polymerase epsilon, a replicative DNA polymerase not normally associated with TLS activity. We asked ourselves if it would be possible to create yeast strains with imbalanced dNTP concentrations in vivo, and, if so, would these imbalances be recognized by the checkpoint control mechanisms in the cell. To address these questions, we focused on the highly conserved loop2 of the allosteric specificity site of yeast Rnr1p. We introduced several mutations into RNR1-loop2 that resulted in changes in the amino acid sequence of the protein. Each of the rnr1-loop2 mutation strains obtained had different levels of individual dNTPs relative to the others. Interestingly, all of the imbalanced dNTP concentrations led to increased mutation rates, but these mutagenic imbalances did not activate the S-phase checkpoint unless one or several dNTPs were present at concentrations that were too low to sustain DNA replication. We were able to use these mutant yeast strains to successfully correlate amino acid substitutions within loop2 of Rnr1p to specific ratios of dNTP concentrations in the cells. We also demonstrated that specific imbalances between the individual dNTP levels result in unique mutation spectra. These mutation spectra suggest that the mutagenesis that results from imbalanced dNTP pools is due to a decrease in fidelity of the replicative DNA polymerases at specific DNA sequences where they are more likely to make a mistake. The mutant rnr1-loop2 strains that we have created with defined dNTP pool imbalances will be of great value for in vivo studies of polymerase fidelity, translesion synthesis by specialized DNA polymerases, and lesion recognition by the DNA repair machinery.
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| 27. |
- Xing, Xuanxuan, et al.
(author)
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A recurrent cancer-associated substitution in DNA polymerase ε produces a hyperactive enzyme
- 2019
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In: Nature Communications. - : Nature Publishing Group. - 2041-1723. ; 10
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Journal article (peer-reviewed)abstract
- Alterations in the exonuclease domain of DNA polymerase ε (Polε) cause ultramutated tumors. Severe mutator effects of the most common variant, Polε-P286R, modeled in yeast suggested that its pathogenicity involves yet unknown mechanisms beyond simple proofreading deficiency. We show that, despite producing a catastrophic amount of replication errors in vivo, the yeast Polε-P286R analog retains partial exonuclease activity and is more accurate than exonuclease-dead Polε. The major consequence of the arginine substitution is a dramatically increased DNA polymerase activity. This is manifested as a superior ability to copy synthetic and natural templates, extend mismatched primer termini, and bypass secondary DNA structures. We discuss a model wherein the cancer-associated substitution limits access of the 3'-terminus to the exonuclease site and promotes binding at the polymerase site, thus stimulating polymerization. We propose that the ultramutator effect results from increased polymerase activity amplifying the contribution of Polε errors to the genomic mutation rate.
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