Project description:Misincorporation of ribonucleotides into DNA during genome replication has recently become recognized as a significant source of genomic instability. The frequency of ribonucleotides in the genome is determined by dNTP/rNTP ratios, the ability of the DNA polymerases to discriminate against ribonucleotides, and by the capacity of repair mechanisms to remove misincorporated ribonucleotides. To simultaneously compare how the nuclear and mitochondrial genomes incorporate and remove ribonucleotides, we challenged these processes by imbalancing cellular dNTP pools. Using a collection of yeast strains with altered dNTP pools, we discovered an inverse relationship between the concentration of individual dNTPs and the amount of the corresponding ribonucleotides incorporated in mitochondrial DNA, while in nuclear DNA the ribonucleotide pattern was only altered in the absence of ribonucleotide excision repair. Our analysis uncovers major differences in ribonucleotide repair between the two genomes and provides concrete evidence that yeast mitochondria lack mechanisms for repair of misincorporated ribonucleotides.

Project description:We have investigated the ability of the 3' exonuclease activity of Saccharomyces cerevisiae DNA polymerase ? (Pol ?) to proofread newly inserted ribonucleotides (rNMPs). During DNA synthesis in vitro, Pol ? proofreads ribonucleotides with apparent efficiencies that vary from none at some locations to more than 90% at others, with rA and rU being more efficiently proofread than rC and rG. Previous studies show that failure to repair ribonucleotides in the genome of rnh201? strains that lack RNase H2 activity elevates the rate of short deletions in tandem repeat sequences. Here we show that this rate is increased by 2-4-fold in pol2-4 rnh201? strains that are also defective in Pol ? proofreading. In comparison, defective proofreading in these same strains increases the rate of base substitutions by more than 100-fold. Collectively, the results indicate that although proofreading of an 'incorrect' sugar is less efficient than is proofreading of an incorrect base, Pol ? does proofread newly inserted rNMPs to enhance genome stability.

Project description:Human mitochondria lack ribonucleotide excision repair pathways, causing misincorporated ribonucleotides (rNMPs) to remain embedded in the mitochondrial genome. Previous studies have demonstrated that human mitochondrial DNA polymerase γ can bypass a single rNMP, but that longer stretches of rNMPs present an obstacle to mitochondrial DNA replication. Whether embedded rNMPs also affect mitochondrial transcription has not been addressed. Here we demonstrate that mitochondrial RNA polymerase elongation activity is affected by a single, embedded rNMP in the template strand. The effect is aggravated at stretches with two or more consecutive rNMPs in a row and cannot be overcome by addition of the mitochondrial transcription elongation factor TEFM. Our findings lead us to suggest that impaired transcription may be of functional relevance in genetic disorders associated with imbalanced nucleotide pools and higher levels of embedded rNMPs.

Project description:Ribonucleotides are estimated to be the most common non-canonical nucleotides transiently incorporated in DNA. Their presence or failure of their removal can affect genome stability and mutations in factors involved in dNTP pool maintenance or ribonucleotide removal can cause Aicardi-Goutières syndrome or promote certain human cancers. Here, we have mapped and quantitated ribonucleotides genome-wide, in nine tissues of wild-type mice. We observed tissue-specific variation in number and base identity of incorporated ribonucleotides and present evidence that a number of genomic features, such as tRNA genes, transcription start sites and G-quadruplexes, can increase the frequency of stably incorporated ribonucleotides in their proximity. Moreover, we present the non-random distribution of incorporated ribonucleotides in mtDNA and identified ribonucleotide hotpots. The study presents a framework to understand the physiological role of ribonucleotides in mammalian DNA.

Project description:Saccharomyces cerevisiae RNase H2 resolves RNA-DNA hybrids formed during transcription and it incises DNA at single ribonucleotides incorporated during nuclear DNA replication. To distinguish between the roles of these two activities in maintenance of genome stability, here we investigate the phenotypes of a mutant of yeast RNase H2 (rnh201-RED; ribonucleotide excision defective) that retains activity on RNA-DNA hybrids but is unable to cleave single ribonucleotides that are stably incorporated into the genome. The rnh201-RED mutant was expressed in wild type yeast or in a strain that also encodes a mutant allele of DNA polymerase ? (pol2-M644G) that enhances ribonucleotide incorporation during DNA replication. Similar to a strain that completely lacks RNase H2 (rnh201?), the pol2-M644G rnh201-RED strain exhibits replication stress and checkpoint activation. Moreover, like its null mutant counterpart, the double mutant pol2-M644G rnh201-RED strain and the single mutant rnh201-RED strain delete 2-5 base pairs in repetitive sequences at a high rate that is topoisomerase 1-dependent. The results highlight an important role for RNase H2 in maintaining genome integrity by removing single ribonucleotides incorporated during DNA replication.

Project description:The chemical identity and integrity of the genome is challenged by the incorporation of ribonucleoside triphosphates (rNTPs) in place of deoxyribonucleoside triphosphates (dNTPs) during replication. Misincorporation is limited by the selectivity of DNA replicases. We show that accumulation of ribonucleoside monophosphates (rNMPs) in the genome causes replication stress and has toxic consequences, particularly in the absence of RNase H1 and RNase H2, which remove rNMPs. We demonstrate that postreplication repair (PRR) pathways-MMS2-dependent template switch and Pol ?-dependent bypass-are crucial for tolerating the presence of rNMPs in the chromosomes; indeed, we show that Pol ? efficiently replicates over 1-4 rNMPs. Moreover, cells lacking RNase H accumulate mono- and polyubiquitylated PCNA and have a constitutively activated PRR. Our findings describe a crucial function for RNase H1, RNase H2, template switch, and translesion DNA synthesis in overcoming rNTPs misincorporated during DNA replication, and may be relevant for the pathogenesis of Aicardi-Goutières syndrome.

Project description:The ribonuclease (RNase) H class of enzymes degrades the RNA component of RNA:DNA hybrids and is important in nucleic acid metabolism. RNase H2 is specialized to remove single ribonucleotides [ribonucleoside monophosphates (rNMPs)] from duplex DNA, and its absence in budding yeast has been associated with the accumulation of deletions within short tandem repeats. Here, we demonstrate that rNMP-associated deletion formation requires the activity of Top1, a topoisomerase that relaxes supercoils by reversibly nicking duplex DNA. The reported studies extend the role of Top1 to include the processing of rNMPs in genomic DNA into irreversible single-strand breaks, an activity that can have distinct mutagenic consequences and may be relevant to human disease.

Project description:Mutations in the human mitochondrial polymerase (polymerase-? (Pol-?)) are associated with various mitochondrial disorders, including mitochondrial DNA (mtDNA) depletion syndrome, Alpers syndrome, and progressive external opthamalplegia. To correlate biochemically quantifiable defects resulting from point mutations in Pol-? with their physiological consequences, we created "humanized" yeast, replacing the yeast mtDNA polymerase (MIP1) with human Pol-?. Despite differences in the replication and repair mechanism, we show that the human polymerase efficiently complements the yeast mip1 knockouts, suggesting common fundamental mechanisms of replication and conserved interactions between the human polymerase and other components of the replisome. We also examined the effects of four disease-related point mutations (S305R, H932Y, Y951N, and Y955C) and an exonuclease-deficient mutant (D198A/E200A). In haploid cells, each mutant results in rapid mtDNA depletion, increased mutation frequency, and mitochondrial dysfunction. Mutation frequencies measured in vivo equal those measured with purified enzyme in vitro. In heterozygous diploid cells, wild-type Pol-? suppresses mutation-associated growth defects, but continuous growth eventually leads to aerobic respiration defects, reduced mtDNA content, and depolarized mitochondrial membranes. The severity of the Pol-? mutant phenotype in heterozygous diploid humanized yeast correlates with the approximate age of disease onset and the severity of symptoms observed in humans.

Project description:We examined the impact of two clinically approved anti-herpes drugs, acyclovir and Forscarnet (phosphonoformate), on the exonuclease activity of the herpes simplex virus-1 DNA polymerase, UL30. Acyclovir triphosphate and Foscarnet, along with the closely related phosphonoacetic acid, did not affect exonuclease activity on single-stranded DNA. Furthermore, blocking the polymerase active site due to either binding of Foscarnet or phosphonoacetic acid to the E-DNA complex or polymerization of acyclovir onto the DNA also had a minimal effect on exonuclease activity. The inability of the exonuclease to excise acyclovir from the primer 3'-terminus results from the altered sugar structure directly impeding phosphodiester bond hydrolysis as opposed to inhibiting binding, unwinding of the DNA by the exonuclease, or transfer of the DNA from the polymerase to the exonuclease. Removing the 3'-hydroxyl or the 2'-carbon from the nucleotide at the 3'-terminus of the primer strongly inhibited exonuclease activity, although addition of a 2'-hydroxyl did not affect exonuclease activity. The biological consequences of these results are twofold. First, the ability of acyclovir and Foscarnet to block dNTP polymerization without impacting exonuclease activity raises the possibility that their effects on herpes replication may involve both direct inhibition of dNTP polymerization and exonuclease-mediated destruction of herpes DNA. Second, the ability of the exonuclease to rapidly remove a ribonucleotide at the primer 3'-terminus in combination with the polymerase not efficiently adding dNTPs onto this primer provides a novel mechanism by which the herpes replication machinery can prevent incorporation of ribonucleotides into newly synthesized DNA.

Project description:In all living cells, DNA is the storage medium for genetic information. Being quite stable, DNA is well-suited for its role in storage and propagation of information, but RNA is also covalently included in DNA through various mechanisms. Recent studies also demonstrate useful aspects of including ribonucleotides in the genome during repair. Therefore, our understanding of the consequences of RNA inclusion into bacterial genomic DNA is just beginning, but with its high frequency of occurrence the consequences and potential benefits are likely to be numerous and diverse. In this review, we discuss the processes that cause ribonucleotide inclusion in genomic DNA, the pathways important for ribonucleotide removal and the consequences that arise should ribonucleotides remain nested in genomic DNA.