Suppression of uracil-DNA glycosylase induces neuronal apoptosis

A chronic imbalance in DNA precursors, caused by one-carbon metabolism impairment, can result in a deficiency of DNA repair and increased DNA damage. Although indirect evidence suggests that DNA damage plays a role in neuronal apoptosis and in the pathogenesis of neurodegenerative disorders, the underlying mechanisms are poorly understood. In particular, very little is known about the role of base excision repair of misincorporated uracil in neuronal survival. To test the hypothesis that repair of DNA damage associated with uracil misincorporation is critical for neuronal survival, we employed an antisense (AS) oligonucleotide directed against uracil-DNA glycosylase encoded by the UNG gene to deplete UNG in cultured rat hippocampal neurons. AS, but not a scrambled control oligonucleotide, induced apoptosis, which was associated with DNA damage analyzed by comet assay and up-regulation of p53. UNG mRNA and protein levels were decreased within 30 min and were undetectable within 6-9 h of exposure to the UNG AS oligonucleotide. Whereas UNG expression is significantly higher in proliferating as compared with nonproliferating cells, such as neurons, the levels of UNG mRNA were increased in brains of cystathionine beta-synthase knockout mice, a model for hyperhomocysteinemia, suggesting that one-carbon metabolism impairment and uracil misincorporation can induce the up-regulation of UNG expression.     

Increased uracil insertion in DNA is cytotoxic and increases the frequency of mutation,double strand break formation and VSG switching in Trypanosoma brucei

Deoxyuridine 5′-triphosphate pyrophosphatase (dUTPase) and uracil-DNA glycosylase (UNG) are key enzymes involved in the control of the presence of uracil in DNA. While dUTPase prevents uracil misincorporation by removing dUTP from the deoxynucleotide pool, UNG excises uracil from DNA as a first step of the base excision repair pathway (BER). Here, we report that strong down-regulation of dUTPase in UNG-deficient Trypanosoma brucei cells greatly impairs cell viability in both bloodstream and procyclic forms, underscoring the extreme sensitivity of trypanosomes to uracil in DNA. Depletion of dUTPase activity in the absence of UNG provoked cell cycle alterations, massive dUTP misincorporation into DNA and chromosomal fragmentation. Overall, trypanosomatid cells that lack dUTPase and UNG activities exhibited greater proliferation defects and DNA damage than cells deficient in only one of these activities. To determine the mutagenic consequences of uracil in DNA, mutation rates and spectra were analyzed in dUTPase-depleted cells in the presence of UNG activity. These cells displayed a spontaneous mutation rate 9-fold higher than the parental cell line. Base substitutions at A:T base pairs and deletion frequencies were both significantly enhanced which is consistent with the generation of mutagenic AP sites and DNA strand breaks. The increase in strand breaks conveyed a concomitant increase in VSG switching in vitro. The low tolerance of T. brucei to uracil in DNA emphasizes the importance of uracil removal and regulation of intracellular dUTP pool levels in cell viability and genetic stability and suggests potential strategies to compromise parasite survival.     

PARP1 Is a TRF2-associated poly(ADP-ribose)polymerase and protects eroded telomeres

Poly(ADP-ribose)polymerase 1 (PARP1) is well characterized for its role in base excision repair (BER), where it is activated by and binds to DNA breaks and catalyzes the poly(ADP-ribosyl)ation of several substrates involved in DNA damage repair. Here we demonstrate that PARP1 associates with telomere repeat binding factor 2 (TRF2) and is capable of poly(ADP-ribosyl)ation of TRF2, which affects binding of TRF2 to telomeric DNA. Immunostaining of interphase cells or metaphase spreads shows that PARP1 is detected sporadically at normal telomeres, but it appears preferentially at eroded telomeres caused by telomerase deficiency or damaged telomeres induced by DNA-damaging reagents. Although PARP1 is dispensable in the capping of normal telomeres, Parp1 deficiency leads to an increase in chromosome end-to-end fusions or chromosome ends without detectable telomeric DNA in primary murine cells after induction of DNA damage. Our results suggest that upon DNA damage, PARP1 is recruited to damaged telomeres, where it can help protect telomeres against chromosome end-to-end fusions and genomic instability.     

Physical and functional interaction of human nuclear uracil-DNA glycosylase with proliferating cell nuclear antigen

Uracil residues arise in DNA by the misincorporation of dUMP in place of dTMP during DNA replication or by the deamination of cytosine in DNA. Uracil-DNA glycosylase initiates DNA base excision repair of uracil residues by catalyzing the hydrolysis of the N-glycosylic bond linking the uracil base to deoxyribose. In human cells, the nuclear form of uracil-DNA glycosylase (UNG2) contains a conserved PCNA-binding motif located at the N-terminus that has been implicated experimentally in binding PCNA. Here we use purified preparations of UNG2 and PCNA to demonstrate that UNG2 physically associates with PCNA. UNG2 co-eluted with PCNA during size exclusion chromatography and bound to a PCNA affinity column. Association of UNG2 with PCNA was abolished by the addition of 100 mM NaCl, and significantly decreased in the presence of 10 mM MgCl(2). The functional significance of the UNG2.PCNA association was demonstrated by UNG2 activity assays. Addition of PCNA (30-810 pmol) to standard uracil-DNA glycosylase reactions containing linear [uracil-(3)H]DNA stimulated UNG2 catalytic activity up to 2.6-fold. UNG2 activity was also stimulated by 7.5 mM MgCl(2). The stimulatory effect of PCNA was increased by the addition of MgCl(2); however, the dependence on PCNA concentration was the same, indicating that the effects of MgCl(2) and PCNA on UNG2 activity occurred by independent mechanisms. Loading of PCNA onto the DNA substrate was required for stimulation, as the activity of UNG2 on circular DNA substrates was not affected by the addition of PCNA. Addition of replication factor C and ATP to reactions containing 90 pmol of PCNA resulted in two-fold stimulation of UNG2 activity on circular DNA.     

DNA excision repair at telomeres

DNA damage is caused by either endogenous cellular metabolic processes such as hydrolysis, oxidation, alkylation, and DNA base mismatches, or exogenous sources including ultraviolet (UV) light, ionizing radiation, and chemical agents. Damaged DNA that is not properly repaired can lead to genomic instability, driving tumorigenesis. To protect genomic stability, mammalian cells have evolved highly conserved DNA repair mechanisms to remove and repair DNA lesions. Telomeres are composed of long tandem TTAGGG repeats located at the ends of chromosomes. Maintenance of functional telomeres is critical for preventing genome instability. The telomeric sequence possesses unique features that predispose telomeres to a variety of DNA damage induced by environmental genotoxins. This review briefly describes the relevance of excision repair pathways in telomere maintenance, with the focus on base excision repair (BER), nucleotide excision repair (NER), and mismatch repair (MMR). By summarizing current knowledge on excision repair of telomere damage and outlining many unanswered questions, it is our hope to stimulate further interest in a better understanding of excision repair processes at telomeres and in how these processes contribute to telomere maintenance.     

Uracil DNA glycosylase (UNG) loss enhances DNA double strand break formation in human cancer cells exposed to pemetrexed

Misincorporation of genomic uracil and formation of DNA double strand breaks (DSBs) are known consequences of exposure to TS inhibitors such as pemetrexed. Uracil DNA glycosylase (UNG) catalyzes the excision of uracil from DNA and initiates DNA base excision repair (BER). To better define the relationship between UNG activity and pemetrexed anticancer activity, we have investigated DNA damage, DSB formation, DSB repair capacity, and replication fork stability in UNG^+/+ and UNG^−/− cells. We report that despite identical growth rates and DSB repair capacities, UNG^−/− cells accumulated significantly greater uracil and DSBs compared with UNG^+/+ cells when exposed to pemetrexed. ChIP-seq analysis of γ-H2AX enrichment confirmed fewer DSBs in UNG^+/+ cells. Furthermore, DSBs in UNG^+/+ and UNG^−/− cells occur at distinct genomic loci, supporting differential mechanisms of DSB formation in UNG-competent and UNG-deficient cells. UNG^−/− cells also showed increased evidence of replication fork instability (PCNA dispersal) when exposed to pemetrexed. Thymidine co-treatment rescues S-phase arrest in both UNG^+/+ and UNG^−/− cells treated with IC₅₀-level pemetrexed. However, following pemetrexed exposure, UNG^−/− but not UNG^+/+ cells are refractory to thymidine rescue, suggesting that deficient uracil excision rather than dTTP depletion is the barrier to cell cycle progression in UNG^−/− cells. Based on these findings we propose that pemetrexed-induced uracil misincorporation is genotoxic, contributing to replication fork instability, DSB formation and ultimately cell death.     

Repair of U/G and U/A in DNA by UNG2-associated repair complexes takes place predominantly by short-patch repair both in proliferating and growth-arrested cells

Nuclear uracil-DNA glycosylase UNG2 has an established role in repair of U/A pairs resulting from misincorporation of dUMP during replication. In antigen-stimulated B-lymphocytes UNG2 removes uracil from U/G mispairs as part of somatic hypermutation and class switch recombination processes. Using antibodies specific for the N-terminal non-catalytic domain of UNG2, we isolated UNG2-associated repair complexes (UNG2-ARC) that carry out short-patch and long-patch base excision repair (BER). These complexes contain proteins required for both types of BER, including UNG2, APE1, POLbeta, POLdelta, XRCC1, PCNA and DNA ligase, the latter detected as activity. Short-patch repair was the predominant mechanism both in extracts and UNG2-ARC from proliferating and less BER-proficient growth-arrested cells. Repair of U/G mispairs and U/A pairs was completely inhibited by neutralizing UNG-antibodies, but whereas added recombinant SMUG1 could partially restore repair of U/G mispairs, it was unable to restore repair of U/A pairs in UNG2-ARC. Neutralizing antibodies to APE1 and POLbeta, and depletion of XRCC1 strongly reduced short-patch BER, and a fraction of long-patch repair was POLbeta dependent. In conclusion, UNG2 is present in preassembled complexes proficient in BER. Furthermore, UNG2 is the major enzyme initiating BER of deaminated cytosine (U/G), and possibly the sole enzyme initiating BER of misincorporated uracil (U/A).     

Uracil incorporation into genomic DNA does not predict toxicity caused by chemotherapeutic inhibition of thymidylate synthase

Thymidylate synthase (TS) is an important target of several chemotherapeutic agents, including 5-FU and raltitrexed (Tomudex). During TS inhibition, TTP levels decrease with a subsequent increase in dUTP. Uracil incorporated into the genome is removed by base excision repair (BER). Thus, BER initiated by uracil DNA glycosylase (UDG) activity has been hypothesized to influence the toxicity induced by TS inhibitors. In this study we created a human cell line expressing the Ugi protein inhibitor of UNG family of UDGs, which reduces cellular UDG activity by at least 45-fold. Genomic uracil incorporation was directly measured by mass spectrometry following treatment with TS inhibitors. Genomic uracil levels were increased over 4-fold following TS inhibition in the Ugi-expressing cells, but did not detectably increase in UNG proficient cells. Despite the difference in genomic uracil levels, there was no difference in toxicity between the UNG proficient and UNG-inhibited cells to folate or nucleotide-based inhibitors of TS. Cell cycle analysis showed that UNG proficient and UNG-inhibited cells arrested in early S-phase and resumed replication progression during recovery from RTX treatment almost identically. The induction of gamma-H2AX was measured following TS inhibition as a measure of whether uracil excision promoted DNA double strand break formation during S-phase arrest. Although gamma-H2AX was detectable following TS inhibition, there was no difference between UNG proficient and UNG-inhibited cells. We therefore conclude that uracil excision initiated by UNG does not adequately explain the toxicity caused by TS inhibition in this model.     

Telomeric epigenetic response mediated by Gadd45a regulates stem cell aging and lifespan

Progressive attrition of telomeres triggers DNA damage response (DDR) and limits the regenerative capacity of adult stem cells during mammalian aging. Intriguingly, telomere integrity is not only determined by telomere length but also by the epigenetic status of telomeric/sub‐telomeric regions. However, the functional interplay between DDR induced by telomere shortening and epigenetic modifications in aging remains unclear. Here, we show that deletion of Gadd45a improves the maintenance and function of intestinal stem cells (ISCs) and prolongs lifespan of telomerase‐deficient mice (G3Terc^?/?). Mechanistically, Gadd45a facilitates the generation of a permissive chromatin state for DDR signaling by inducing base excision repair‐dependent demethylation of CpG islands specifically at sub‐telomeric regions of short telomeres. Deletion of Gadd45a promotes chromatin compaction in sub‐telomeric regions and attenuates DDR initiation at short telomeres of G3Terc^?/? ISCs. Treatment with a small molecule inhibitor of base excision repair reduces DDR and improves the maintenance and function of G3Terc^?/? ISCs. Taken together, our study proposes a therapeutic approach to enhance stem cell function and prolong lifespan by targeting epigenetic modifiers.     

Genomic uracil and human disease

Uracil is present in small amounts in DNA due to spontaneous deamination of cytosine and incorporation of dUMP during replication. While deamination generates mutagenic U:G mismatches, incorporated dUMP results in U:A pairs that are not directly mutagenic, but may be cytotoxic. In most cells, mutations resulting from uracil in DNA are prevented by error-free base excision repair. However, in B-cells uracil in DNA is also a physiological intermediate in acquired immunity. Here, activation-induced cytosine deaminase (AID) introduces template uracils that give GC to AT transition mutations in the Ig locus after replication. When uracil-DNA glycosylase (UNG2) removes uracil, error-prone translesion synthesis over the abasic site causes other mutations in the Ig locus. Together, these processes are central to somatic hypermutation (SHM) that increases immunoglobulin diversity. AID and UNG2 are also essential for generation of strand breaks that initiate class switch recombination (CSR). Patients lacking UNG2 display a hyper-IgM syndrome with recurrent infections, increased IgM, strongly decreased IgG, IgA and IgE and skewed SHM. UNG2 is also involved in innate immune response against retroviral infections. Ung(-/-) mice have a similar phenotype and develop B-cell lymphomas late in life. However, there is no evidence indicating that UNG deficiency causes lymphomas in humans.     

Base excision repair of DNA in mammalian cells

Base excision repair (BER) of DNA corrects a number of spontaneous and environmentally induced genotoxic or miscoding base lesions in a process initiated by DNA glycosylases. An AP endonuclease cleaves at the 5' side of the abasic site and the repair process is subsequently completed via either short patch repair or long patch repair, which largely require different proteins. As one example, the UNG gene encodes both nuclear (UNG2) and mitochondrial (UNG1) uracil DNA glycosylase and prevents accumulation of uracil in the genome. BER is likely to have a major role in preserving the integrity of DNA during evolution and may prevent cancer.     

Trypanosomes lacking uracil-DNA glycosylase are hypersensitive to antifolates and present a mutator phenotype

Cells contain low amounts of uracil in DNA which can be the result of dUTP misincorporation during replication or cytosine deamination. Elimination of uracil in the base excision repair pathway yields an abasic site, which is potentially mutagenic unless repaired. The Trypanosoma brucei genome presents a single uracil-DNA glycosylase responsible for removal of uracil from DNA. Here we establish that no excision activity is detected on U:G, U:A pairs or single-strand uracil-containing DNA in uracil-DNA glycosylase null mutant cell extracts, indicating the absence of back-up uracil excision activities. While procyclic forms can survive with moderate amounts of uracil in DNA, an analysis of the mutation rate and spectra in mutant cells revealed a hypermutator phenotype where the predominant events were GC to AT transitions and insertions. Defective elimination of uracil via the base excision repair pathway gives rise to hypersensitivity to antifolates and oxidative stress and an increased number of DNA strand breaks, suggesting the activation of alternative DNA repair pathways. Finally, we show that uracil-DNA glycosylase defective cells exhibit reduced infectivity in vivo demonstrating that efficient uracil elimination is important for survival within the mammalian host.     

人尿嘧啶糖基化酶cDNA的克隆及其在食管鳞癌组织中的检测

尿嘧啶糖基化酶是碱基切除修复过程的起始酶,对于维护基因稳定具有重要意义。在不同组织及不同细胞周期中,该酶的表达水平存在差异。通过反转录PCR克隆了人尿嘧啶糖基化酶的cDNA编码序列,进一步以克隆所得的已知UNG基因拷贝数的重组质粒作为定量标准,通过实时荧光定量RT-PCR测定了食管癌病人手术切除组织中尿嘧啶糖基化酶的mRNA水平,探讨了尿嘧啶糖基化酶表达水平与食管癌之间的联系。     

The role of telomere trimming in normal telomere length dynamics

Telomeres consist of repetitive DNA and associated proteins that protect chromosome ends from illicit DNA repair. It is well known that telomeric DNA is progressively eroded during cell division, until telomeres become too short and the cell stops dividing. There is a second mode of telomere shortening, however, which is a regulated form of telomere rapid deletion (TRD) termed telomere trimming that is reviewed here. Telomere trimming appears to involve resolution of recombination intermediate structures, which shortens the telomere by release of extrachromosomal telomeric DNA. This has been detected in human and in mouse cells and occurs both in somatic and germline cells, where it sets an upper limit on telomere length and contributes to a length equilibrium set-point in cells that have a telomere elongation mechanism. Telomere trimming thus represents an additional mechanism of telomere length control that contributes to normal telomere dynamics and cell proliferative potential.     

Poxvirus uracil‐DNA glycosylase—An unusual member of the family I uracil‐DNA glycosylases

Uracil‐DNA glycosylases are ubiquitous enzymes, which play a key role repairing damages in DNA and in maintaining genomic integrity by catalyzing the first step in the base excision repair pathway. Within the superfamily of uracil‐DNA glycosylases family I enzymes or UNGs are specific for recognizing and removing uracil from DNA. These enzymes feature conserved structural folds, active site residues and use common motifs for DNA binding, uracil recognition and catalysis. Within this family the enzymes of poxviruses are unique and most remarkable in terms of amino acid sequences, characteristic motifs and more importantly for their novel non‐enzymatic function in DNA replication. UNG of vaccinia virus, also known as D4, is the most extensively characterized UNG of the poxvirus family. D4 forms an unusual heterodimeric processivity factor by attaching to a poxvirus‐specific protein A20, which also binds to the DNA polymerase E9 and recruits other proteins necessary for replication. D4 is thus integrated in the DNA polymerase complex, and its DNA‐binding and DNA scanning abilities couple DNA processivity and DNA base excision repair at the replication fork. The adaptations necessary for taking on the new function are reflected in the amino acid sequence and the three‐dimensional structure of D4. An overview of the current state of the knowledge on the structure‐function relationship of D4 is provided here.     

Direct interaction between XRCC1 and UNG2 facilitates rapid repair of uracil in DNA by XRCC1 complexes

Uracil-DNA glycosylase, UNG2, interacts with PCNA and initiates post-replicative base excision repair (BER) of uracil in DNA. The DNA repair protein XRCC1 also co-localizes and physically interacts with PCNA. However, little is known about whether UNG2 and XRCC1 directly interact and participate in a same complex for repair of uracil in replication foci. Here, we examine localization pattern of these proteins in live and fixed cells and show that UNG2 and XRCC1 are likely in a common complex in replication foci. Using pull-down experiments we demonstrate that UNG2 directly interacts with the nuclear localization signal-region (NLS) of XRCC1. Western blot and functional analysis of immunoprecipitates from whole cell extracts prepared from S-phase enriched cells demonstrate the presence of XRCC1 complexes that contain UNG2 in addition to separate XRCC1 and UNG2 associated complexes with distinct repair features. XRCC1 complexes performed complete repair of uracil with higher efficacy than UNG2 complexes. Based on these results, we propose a model for a functional role of XRCC1 in replication associated BER of uracil.     

Telomerase deficiency affects the formation of chromosomal translocations by homologous recombination in Saccharomyces cerevisiae

Telomerase is a ribonucleoprotein complex required for the replication and protection of telomeric DNA in eukaryotes. Cells lacking telomerase undergo a progressive loss of telomeric DNA that results in loss of viability and a concomitant increase in genome instability. We have used budding yeast to investigate the relationship between telomerase deficiency and the generation of chromosomal translocations, a common characteristic of cancer cells. Telomerase deficiency increased the rate of formation of spontaneous translocations by homologous recombination involving telomere proximal sequences during crisis. However, telomerase deficiency also decreased the frequency of translocation formation following multiple HO-endonuclease catalyzed DNA double-strand breaks at telomere proximal or distal sequences before, during and after crisis. This decrease correlated with a sequestration of the central homologous recombination factor, Rad52, to telomeres determined by chromatin immuno-precipitation. This suggests that telomerase deficiency results in the sequestration of Rad52 to telomeres, limiting the capacity of the cell to repair double-strand breaks throughout the genome. Increased spontaneous translocation formation in telomerase-deficient yeast cells undergoing crisis is consistent with the increased incidence of cancer in elderly humans, as the majority of our cells lack telomerase. Decreased translocation formation by recombinational repair of double-strand breaks in telomerase-deficient yeast suggests that the reemergence of telomerase expression observed in many human tumors may further stimulate genome rearrangement. Thus, telomerase may exert a substantial effect on global genome stability, which may bear significantly on the appearance and progression of cancer in humans.     

Inter-telomeric recombination is present in telomerase-positive human cells

Immortal cells require a mechanism of telomere length control in order to divide infinitely. One mechanism is telomerase, an enzyme that compensates the loss of telomeric DNA. The second mechanism is the alternative lengthening of telomeres (ALT) pathway. In ALT pathway cells, homologous recombination between telomeric DNA is the mechanism by which telomere homeostasis is achieved. We developed a novel homologous recombination reporter system that is able to measure inter-telomeric recombination in a sensitive manner. We asked the fundamental question if homologous recombination between different telomeres is present in telomerase-positive cells. In this in vitro study, we showed that homologous recombination between telomeres is detectable in ALT cells with the same frequency as in cells that utilize the telomerase pathway. We further described an ALT cell clone that showed peaks of recombination which were not detected in telomerase-positive clones. In telomerase-positive cells the frequency of inter-telomeric recombination was not increased by shortened telomeres or by a fragile telomere phenotype induced with aphidicolin. ALT cells, in contrast, responded to aphidicolin with an increase in the frequency of recombination. Our results indicate that inter-telomeric recombination is present in both pathways of telomere length control, but the factors that increase recombination are different in ALT and telomerase-positive cells.