The high cost of living. American Association for Cancer Research Special Conference: endogenous sources of mutations, Fort Myers, Florida, USA, 11-15 November 1998

Annexin A1 as a Regulator of Immune Response in Cancer

Annexin A1 is a 37 kDa phospholipid-binding protein that is expressed in many tissues and cell types, including leukocytes, lymphocytes and epithelial cells. Although Annexin A1 has been extensively studied for its anti-inflammatory activity, it has been shown that, in the cancer context, its activity switches from anti-inflammatory to pro-inflammatory. Remarkably, Annexin A1 shows pro-invasive and pro-tumoral properties in several cancers either by eliciting autocrine signaling in cancer cells or by inducing a favorable tumor microenvironment. Indeed, the signaling of the N-terminal peptide of AnxA1 has been described to promote the switching of macrophages to the pro-tumoral M2 phenotype. Moreover, AnxA1 has been described to prevent the induction of antigen-specific cytotoxic T cell response and to play an essential role in the induction of regulatory T lymphocytes. In this way, Annexin A1 inhibits the anti-tumor immunity and supports the formation of an immunosuppressed tumor microenvironment that promotes tumor growth and metastasis. For these reasons, in this review we aim to describe the role of Annexin A1 in the establishment of the tumor microenvironment, focusing on the immunosuppressive and immunomodulatory activities of Annexin A1 and on its interaction with the epidermal growth factor receptor.

Global warming overrides physiological anti-predatory mechanisms in intertidal rock pool fish Gobius paganellus

In nature, a multitude of factors influences the fitness of an organism at a given time, which makes single stressor assessments far from ecologically relevant scenarios. This study focused on the effects of water temperature and predation stress on the metabolism and body mass gain of a common intertidal rock pool fish, Gobius paganellus, addressing the following hypotheses: (1) the energy metabolism of G. paganellus under predation stress is reduced; (2) G. paganellus shows thermal compensation under heat stress; and (3) thermal stress is the dominant stressor that may override predation stress responses. Individuals were exposed to simulated predation stress and temperature increase from 20 °C to 29 °C, and both stressors combined. Physiological effects were addressed using biochemical biomarkers related with energy metabolism (isocitrate dehydrogenase, lactate dehydrogenase, energy available, energy consumption rates), oxidative stress (superoxide dismutase, catalase, DNA damage, lipid peroxidation), and biotransformation (glutathione-S-transferase). The results of this study revealed that predation stress reduced the cellular metabolism of G. paganellus, and enhanced storage of protein reserves. As hypothesized, hyperthermia decreased the aerobic mitochondrial metabolism, indicating thermal compensation mechanisms to resist against unfavourable temperatures. Hyperthermia was the dominant stressor overriding the physiological responses to predation stress. Both stressors combined might further have synergistically activated detoxification pathways, even though not strong enough to counteract lipid peroxidation and DNA damage completely. The synergistic effect of combined thermal and predation stress thus may not only increase the risk of being preyed upon, but also may indicate extra energy trade-off for the basal metabolism, which in turn may have ecologically relevant consequences for general body functions such as somatic growth and reproduction. The present findings clearly underline the ecological importance of multi-stressor assessments to provide a better and holistic picture of physiological responses towards more realistic evaluations of climate change consequences for intertidal populations.

The abundant DNA adduct N 7-methyl deoxyguanosine contributes to miscoding during replication by human DNA polymerase η

Aside from abasic sites and ribonucleotides, the DNA adduct N ⁷-methyl deoxyguanosine (N⁷ -CH₃ dG) is one of the most abundant lesions in mammalian DNA. Because N⁷ -CH₃ dG is unstable, leading to deglycosylation and ring-opening, its miscoding potential is not well-understood. Here, we employed a 2'-fluoro isostere approach to synthesize an oligonucleotide containing an analog of this lesion (N⁷ -CH₃ 2'-F dG) and examined its miscoding potential with four Y-family translesion synthesis DNA polymerases (pols): human pol (hpol) η, hpol κ, and hpol ι and Dpo4 from the archaeal thermophile Sulfolobus solfataricus We found that hpol η and Dpo4 can bypass the N⁷ -CH₃ 2'-F dG adduct, albeit with some stalling, but hpol κ is strongly blocked at this lesion site, whereas hpol ι showed no distinction with the lesion and the control templates. hpol η yielded the highest level of misincorporation opposite the adduct by inserting dATP or dTTP. Moreover, hpol η did not extend well past an N ⁷-CH₃ 2'-F dG:dT mispair. MS-based sequence analysis confirmed that hpol η catalyzes mainly error-free incorporation of dC, with misincorporation of dA and dG in 5-10% of products. We conclude that N ⁷-CH₃ 2'-F dG and, by inference, N ⁷-CH₃ dG have miscoding and mutagenic potential. The level of misincorporation arising from this abundant adduct can be considered as potentially mutagenic as a highly miscoding but rare lesion.

Annexin A1 localization and its relevance to cancer

Annexin A1 (ANXA1) is a Ca(2+)-regulated phospholipid-binding protein involved in various cell processes. ANXA1 was initially widely studied in inflammation resolution, but its overexpression was later reported in a large number of cancers. Further in-depth investigations have revealed that this protein could have many roles in cancer progression and act at different levels (from cancer initiation to metastasis). This is partly due to the location of ANXA1 in different cell compartments. ANXA1 can be nuclear, cytoplasmic and/or membrane associated. This last location allows ANXA1 to be proteolytically cleaved and/or to become accessible to its cognate partners, the formyl-peptide receptors. Indeed, in some cancers, ANXA1 is found at the cell surface, where it stimulates formyl-peptide receptors to trigger oncogenic pathways. In the present review, we look at the different locations of ANXA1 and their association with the deregulated pathways often observed in cancers. We have specifically detailed the non-classic pathways of ANXA1 externalization, the significance of its cleavage and the role of the ANXA1-formyl-peptide receptor complex in cancer progression.

Insights into the substrate specificity of the MutT pyrophosphohydrolase using structural analogues of 8-oxo-2'-deoxyguanosine nucleotide

The bacterial repair enzyme MutT hydrolyzes the damaged nucleotide OdGTP (the 5'-triphosphate derivative of 8-oxo-2'-deoxyguanosine; OdG), which is a known mutagen and has been linked to antibacterial action. Previous work has indicated important roles for the C8-oxygen, N7-hydrogen, and C2-exocyclic amine during OdGTP recognition by MutT. In order to gain a more nuanced understanding of the contribution of these three sites to the overall activity of MutT, we determined the reaction parameters for dGTP, OdGTP, and nine of their analogues using steady state kinetics. Our results indicate that overall high reaction efficiencies can be achieved despite altering any one of these sites. However, altering two or more sites leads to a significant decrease in efficiency. The data also suggest that, similar to another bacterial OdG repair enzyme, MutM, a specific carbonyl in the enzyme can not only promote activity by forming an active site hydrogen bond with the N7-hydrogen of OdGTP, but can also hinder activity through electrostatic repulsion with the N7-lone pair of dGTP.

A dynamic checkpoint in oxidative lesion discrimination by formamidopyrimidine-DNA glycosylase

In contrast to proteins recognizing small-molecule ligands, DNA-dependent enzymes cannot rely solely on interactions in the substrate-binding centre to achieve their exquisite specificity. It is widely believed that substrate recognition by such enzymes involves a series of conformational changes in the enzyme-DNA complex with sequential gates favoring cognate DNA and rejecting nonsubstrates. However, direct evidence for such mechanism is limited to a few systems. We report that discrimination between the oxidative DNA lesion, 8-oxoguanine (oxoG) and its normal counterpart, guanine, by the repair enzyme, formamidopyrimidine-DNA glycosylase (Fpg), likely involves multiple gates. Fpg uses an aromatic wedge to open the Watson-Crick base pair and everts the lesion into its active site. We used molecular dynamics simulations to explore the eversion free energy landscapes of oxoG and G by Fpg, focusing on structural and energetic details of oxoG recognition. The resulting energy profiles, supported by biochemical analysis of site-directed mutants disturbing the interactions along the proposed path, show that Fpg selectively facilitates eversion of oxoG by stabilizing several intermediate states, helping the rapidly sliding enzyme avoid full extrusion of every encountered base for interrogation. Lesion recognition through multiple gating intermediates may be a common theme in DNA repair enzymes.

Lack of association between polymorphisms of the DNA base excision repair genes MUTYH and hOGG1 and keratoconus in a Polish subpopulation

INTRODUCTION

Keratoconus (KC) is a non-inflammatory thinning of the cornea and a leading indication for corneal transplantation. Oxidative stress plays a role in the pathogenesis of this disease. The products of the hOGG1 and MUTYH genes play an important role in the repair of oxidatively modified DNA in the base excision repair pathway. We hypothesized that variability in these genes may change susceptibility to oxidative stress and predispose individuals to the development of KC. We investigated the possible association between the c.977C>G polymorphism of the hOGG1 gene (rs1052133) and the c.972G>C polymorphism of the MUTYH gene (rs3219489) and KC occurrence as well as the modulation of this association by some KC risk factors.

MATERIAL AND METHODS

A total of 205 patients with KC and 220 controls were included in this study. The polymorphisms were genotyped with polymerase chain reaction (PCR) restriction fragment length polymorphism and PCR-confronting two-pair primer techniques. Differences in genotype and allele frequency distributions were evaluated using the χ(2) test, and KC risk was estimated with an unconditional multiple logistic regression with and without adjustment for co-occurrence of visual impairment, allergies, sex and family history for KC.

RESULTS

We did not find any association between the genotypes and combined genotypes of the c.977C>G polymorphism of the hOGG1 gene and the c.972G>C polymorphism of the MUTYH gene and the occurrence of KC.

CONCLUSIONS

Our findings suggest that the c.977C>G-hOGG1 polymorphism and the c.972G>C-MUTYH polymorphism may not be linked with KC occurrence in this Polish subpopulation.

A versatile new tool to quantify abasic sites in DNA and inhibit base excision repair

A number of endogenous and exogenous agents, and cellular processes create abasic (AP) sites in DNA. If unrepaired, AP sites cause mutations, strand breaks and cell death. Aldehyde-reactive agent methoxyamine reacts with AP sites and blocks their repair. Another alkoxyamine, ARP, tags AP sites with a biotin and is used to quantify these sites. We have combined both these abilities into one alkoxyamine, AA3, which reacts with AP sites with a better pH profile and reactivity than ARP. Additionally, AA3 contains an alkyne functionality for bioorthogonal click chemistry that can be used to link a wide variety of biochemical tags to AP sites. We used click chemistry to tag AP sites with biotin and a fluorescent molecule without the use of proteins or enzymes. AA3 has a better reactivity profile than ARP and gives much higher product yields at physiological pH than ARP. It is simpler to use than ARP and its use results in lower background and greater sensitivity for AP site detection. We also show that AA3 inhibits the first enzyme in the repair of abasic sites, APE-1, to about the same extent as methoxyamine. Furthermore, AA3 enhances the ability of an alkylating agent, methylmethane sulfonate, to kill human cells and is more effective in such combination chemotherapy than methoxyamine.

Ribonucleotides in DNA: origins, repair and consequences

While primordial life is thought to have been RNA-based (Cech, Cold Spring Harbor Perspect. Biol. 4 (2012) a006742), all living organisms store genetic information in DNA, which is chemically more stable. Distinctions between the RNA and DNA worlds and our views of "DNA" synthesis continue to evolve as new details emerge on the incorporation, repair and biological effects of ribonucleotides in DNA genomes of organisms from bacteria through humans.

Association between polymorphisms of the DNA base excision repair genes MUTYH and hOGG1 and age-related macular degeneration

Age-Related Macular Degeneration (AMD) is an eye disease that results in progressive and irreversible loss of central vision and is considered as the primary cause of visual impairment, including blindness, in the elderly in industrialized countries. Oxidative stress has been implicated in the pathogenesis of AMD. The hOGG1 and the MUTYH genes play an important role in the repair of oxidatively damaged DNA in the base excision repair pathway. The DNA glycosylases encoded by the hOGG1 and MUTYH genes initiate this pathway by recognizing and removing 8-oxoguanine and adenine paired with 8-oxoguanine, respectively. Our study was designed to examine the association between the c.977C>G polymorphism (rs1052133) of the hOGG1 gene and the c.972G>C polymorphism (rs3219489) of the MUTYH gene and AMD as well as the modulation of this association by some clinical and lifestyle factors. Genotypes were determined in DNA from blood of 271 AMD patients, including 101 with wet and 170 with dry form of the disease and 105 sex- and age-matched individuals without AMD. We observed an association between AMD, dry and wet forms of AMD and the C/G genotype and the G allele of the c.977C>G-hOGG1 polymorphism (p 0.006; 0.009; 0.021 and 0.004; 0.005; 0.016 respectively). On the other hand, the C/C genotype and the C allele reduced the risk of AMD as well as of its dry form or wet form (p 0.002; 0.003; 0.010 and 0.004; 0.005; 0.016, respectively). Therefore, the associations we detected were driven by the dry AMD. We observed some statistically significant association between the occurrence of AMD and its dry and wet forms and genotypes of the other polymorphism, the c.972G>C-MUTYH polymorphism, but due to borderline character of all this association we do not consider them as medically relevant. Our findings suggest that the c.977C>G-hOGG1 polymorphism may be associated with dry AMD. Further studies are needed to determine possible association between AMD and the c.972G>C-MUTYH polymorphism.

High levels of somatic DNA diversity at the myotonic dystrophy type 1 locus are driven by ultra-frequent expansion and contraction mutations

Several human genetic diseases are associated with inheriting an abnormally large unstable DNA simple sequence repeat. These sequences mutate, by changing the number of repeats, many times during the lifetime of those affected, with a bias towards expansion. These somatic changes lead not only to the presence of cells with different numbers of repeats in the same tissue, but also produce increasingly longer repeats, contributing towards the progressive nature of the symptoms. Modelling the progression of repeat length throughout the lifetime of individuals has potential for improving prognostic information as well as providing a deeper understanding of the underlying biological process. A large data set comprising blood DNA samples from individuals with one such disease, myotonic dystrophy type 1, provides an opportunity to parameterize a mathematical model for repeat length evolution that we can use to infer biological parameters of interest. We developed new mathematical models by modifying a proposed stochastic birth process to incorporate possible contraction. A hierarchical Bayesian approach was used as the basis for inference, and we estimated the distribution of mutation rates in the population. We used model comparison analysis to reveal, for the first time, that the expansion bias observed in the distributions of repeat lengths is likely to be the cumulative effect of many expansion and contraction events. We predict that mutation events can occur as frequently as every other day, which matches the timing of regular cell activities such as DNA repair and transcription but not DNA replication.

Oligonucleotide incorporation and base pair stability of 9-deaza-2'-deoxyguanosine, an analogue of 8-oxo-2'-deoxyguanosine

9-Deaza-2'-deoxyguanosine (CdG) is a C-nucleoside and an analogue of the abundant promutagen 8-oxo-2'-deoxyguanosine (OdG). Like 2'-deoxyguanosine (dG), CdG should form a stable base pair with dC, but similar to OdG, CdG contains an N7-hydrogen that should allow it to also form a relatively stable base pair with dA. In order to further investigate the base pairing of CdG, it was incorporated into DNA and paired with either dC or dA. Melting studies revealed CdG:dC base pairs are less stable than dG:dC base pairs, while CdG:dA base pairs are less stable than OdG:dA base pairs. In order to gain a deeper understanding of these results, quantum studies on model structures of nucleoside monomers and base pairs were performed, the results of which indicate that (i) CdG:dC base pairs are likely destabilized relative to dG:dC as a result of structural constraints imposed by the C-nucleotide character of CdG, and (ii) CdG:dA base pairs may be less stable than OdG:dA base pairs, at least in part, because of a third long-range interaction that is possible in OdG:dA but not in CdG:dA.

Early Steps in the DNA Base Excision Repair Pathway of a Fission Yeast Schizosaccharomyces pombe

DNA base excision repair (BER) accounts for maintaining genomic integrity by removing damaged bases that are generated endogenously or induced by genotoxic agents. In this paper, we describe the roles of enzymes functioning in the early steps of BER in fission yeast. Although BER is an evolutionarily conserved process, some unique features of the yeast repair pathway were revealed by genetic and biochemical approaches. AP sites generated by monofunctional DNA glycosylases are incised mainly by AP lyase activity of Nth1p, a sole bifunctional glycosylase in yeast, to leave a blocked 3′ end. The major AP endonuclease Apn2p functions predominantly in removing the 3′ block. Finally, a DNA polymerase fills the gap, and a DNA ligase seals the nick (Nth1p-dependent or short patch BER). Apn1p backs up Apn2p. In long patch BER, Rad2p endonuclease removes flap DNA containing a lesion after DNA synthesis. A UV-specific endonuclease Uve1p engages in an alternative pathway by nicking DNA on the 5′ side of oxidative damage. Nucleotide excision repair and homologous recombination are involved in repair of BER intermediates including the AP site and single-strand break with the 3′ block. Other enzymes working in 3′ end processing are also discussed.

DNA polymerases involved in the incorporation of oxidized nucleotides into DNA: their efficiency and template base preference

Genetic information must be duplicated with precision and accurately passed on to daughter cells and later generations. In order to achieve this goal, DNA polymerases (Pols) have to faithfully execute DNA synthesis during chromosome replication and repair. However, the conditions under which Pols synthesize DNA are not always optimal; the template DNA can be damaged by various endogenous and exogenous genotoxic agents including reactive oxygen species (ROS), and ROS oxidize dNTPs in the nucleotide pool from which Pols elongate DNA strands. Both damaged DNA and oxidized dNTPs interfere with faithful DNA synthesis by Pols, inducing various cellular abnormalities, such as mutations, cancer, neurological diseases, and cellular senescence. In this review, we focus on the process by which Pols incorporate oxidized dNTPs into DNA and compare the properties of Pols: efficiency, i.e., k(cat)/K(m), k(pol)/K(d) or V(max)/K(m), and template base preference for the incorporation of 8-oxo-dGTP, an oxidized form of dGTP. In general, Pols involved in chromosome replication, the A- and B-family Pols, are resistant to the incorporation of 8-oxo-dGTP, whereas Pols involved in repair and/or translesion synthesis, the X- and Y-family Pols, incorporate nucleotides in a relatively efficient manner and tend to incorporate it opposite template dA rather than template dC, though there are several exceptions. We discuss the molecular mechanisms by which Pols exhibit different template base preferences for the incorporation of 8-oxo-dGTP and how Pols are involved in the induction of mutations via the incorporation of oxidized nucleotides under oxidative stress.

Chemical biology of mutagenesis and DNA repair: cellular responses to DNA alkylation

The reaction of DNA-damaging agents with the genome results in a plethora of lesions, commonly referred to as adducts. Adducts may cause DNA to mutate, they may represent the chemical precursors of lethal events and they can disrupt expression of genes. Determination of which adduct is responsible for each of these biological endpoints is difficult, but this task has been accomplished for some carcinogenic DNA-damaging agents. Here, we describe the respective contributions of specific DNA lesions to the biological effects of low molecular weight alkylating agents.

DNA damage and repair: from molecular mechanisms to health implications

DNA is subjected to several modifications, resulting from endogenous and exogenous sources. The cell has developed a network of complementary DNA-repair mechanisms, and in the human genome, >130 genes have been found to be involved. Knowledge about the basic mechanisms for DNA repair has revealed an unexpected complexity, with overlapping specificity within the same pathway, as well as extensive functional interactions between proteins involved in repair pathways. Unrepaired or improperly repaired DNA lesions have serious potential consequences for the cell, leading to genomic instability and deregulation of cellular functions. A number of disorders or syndromes, including several cancer predispositions and accelerated aging, are linked to an inherited defect in one of the DNA-repair pathways. Genomic instability, a characteristic of most human malignancies, can also arise from acquired defects in DNA repair, and the specific pathway affected is predictive of types of mutations, tumor drug sensitivity, and treatment outcome. Although DNA repair has received little attention as a determinant of drug sensitivity, emerging knowledge of mutations and polymorphisms in key human DNA-repair genes may provide a rational basis for improved strategies for therapeutic interventions on a number of tumors and degenerative disorders.

Expression of the E. coli fpg protein in CHO cells lowers endogenous oxypurine clustered damage levels and decreases accumulation of endogenous Hprt mutations

Endogenous DNA damage clusters--two or more oxidized bases, abasic sites, or strand breaks within about 20 base pairs on opposing strands--can accumulate in unirradiated mammalian cells, and may be significant origins of spontaneous detrimental biological effects. Factors determining the levels of such endogenous clusters are largely unknown. To determine if cellular repair genotype can affect endogenous cluster levels in mammalian cells, the authors examined cluster levels, growth rates, and mutant frequencies in Chinese hamster ovary cells expressing the Escherichia coli glycosylase fpg protein, whose principal substrates are oxidized purines. In cells expressing high levels of fpg protein, the levels of oxypurine clustered damages were decreased while those of oxypyrimidine clusters and abasic clusters were unchanged. Furthermore, in these cells, the growth rates were increased and the level of spontaneous background mutants in the hypoxanthine guanine phosphoribosyl transferase gene was decreased. These results suggest that endogenous clusters are potentially detrimental DNA damages, and that their levels-as well as the detrimental consequences of their presence-can be effectively reduced by increased cellular activity of specific DNA repair proteins.

Modulation of oxidative mutagenesis and carcinogenesis by polymorphic forms of human DNA repair enzymes

Chromosome DNA is continuously exposed to various endogenous and exogenous mutagens. Among them, oxidation is one of the most common threats to genetic stability, and multiple DNA repair enzymes protect chromosome DNA from the oxidative damage. In Escherichia coli, three repair enzymes synergistically reduce the mutagenicity of oxidized base 8-hydroxy-guanine (8-OH-G). MutM DNA glycosylase excises 8-OH-G from 8-OH-G:C pairs in DNA and MutY DNA glycosylase removes adenine incorporated opposite template 8-OH-G during DNA replication. MutT hydrolyzes 8-OH-dGTP to 8-OH-dGMP in dNTP pool, thereby reducing the chance of misincorporation of 8-OH-dGTP by DNA polymerases. Simultaneous inactivation of MutM and MutY dramatically increases the frequency of spontaneous G:C to T:A mutations, and the deficiency of MutT leads to the enhancement of T:A to G:C transversions more than 1000-fold over the control level. In humans, the functional homologues of MutM, MutY and MutT, i.e., OGG1, MUTYH (MYH) and MTH1, contribute to the protection of genomic DNA from oxidative stress. Interestingly, several polymorphic forms of these proteins exist in human populations, and some of them are suggested to be associated with cancer susceptibility. Here, we review the polymorphic forms of OGG1, MUTYH and MTH1 involved in repair of 8-OH-G and 8-OH-dGTP, and discuss the significance of the polymorphisms in the maintenance of genomic integrity. We also summarize the polymorphic forms of human DNA polymerase eta, which may be involved in damage tolerance and mutagenesis induced by oxidative stress.

Commentary: DNA base excision repair defects in human pathologies

DNA base excision repair (BER) is the main pathway for repair of endogenous damage in human cells. It was expected that a number of degenerative diseases could derive from BER defects. On the contrary, the link between BER defects and human pathology is elusive and the literature is full of conflicting results. The fact that most studies have investigated DNA variations but not their functional consequences has probably contributed to this confusing picture. From a functional point of view, it is likely that gross BER defects are simply not compatible with life and only limited reductions can be observed. Notwithstanding those limits, the pathological consequences of partial BER defects might be widespread and significant at the population level. This starts to emerge in particular for colorectal and lung cancer.

Modulation of human dUTPase using small interfering RNA

Deoxyuridine triphosphate nucleotidohydrolase (dUTPase) is responsible for maintaining low intracellular levels of dUTP, thus preventing the incorporation of dUTP into DNA. A 21 bp double-stranded RNA molecule (siRNAdUT3) targeted against motif 3 of human dUTPase resulted in a time- and dose-dependent decrease in dUTPase activity in transfected cells. dUTPase activity was reduced approximately 95+/-5% in all cell lines tested 48 h after transfection with 2 microg siRNAdUT3 and it was maintained at this decreased level for at least 72 h. Down-regulation of dUTPase resulted in a significant increase in intracellular dUTP and a decreased proliferation of the transfected cells. Therefore, we conclude that dUTPase activity/expression can be down-regulated using siRNA specifically targeted to dUTPase mRNA and that this approach can be used to elucidate the role of dUTPase in DNA metabolism, as well as, to determine whether dUTPase is a valid target for drug development.

Repair of 8 oxoguanine in mammalian cells expressing the Drosophila S3 ribosomal/repair protein

8-oxo-7,8-dihydroguanine (8-oxoG) is a potent mutagenic lesion that forms at elevated levels in cellular DNA and is repaired with low efficiency in human cells. Unlike its human counterpart, the Drosophila S3 ribosomal/repair protein is endowed with a vigorous 8 oxoG repair activity that is associated to beta,delta-elimination AP lyase activity. We have recently observed that pure GST-tagged Drosophila S3 protein can significantly accelerate the in vitro repair of 8 oxoG performed by human and mouse cell extracts [Cappelli et al., unpublished data]. In this work, we have transfected Chinese hamster cells with mammalian expression vectors containing the Drosophila S3 cDNA. The cells synthesized both S3 mRNA and protein but no improved repair of 8 oxoguanine was observed. Factors important for the proper expression of Drosophila genes in mammalian cells are discussed.

Effects of endogenous DNA base lesions on transcription elongation by mammalian RNA polymerase II. Implications for transcription-coupled DNA repair and transcriptional mutagenesis

The blockage of transcription elongation by RNA polymerase II (pol II) is thought to be a trigger for transcription-coupled repair in the pathway of nucleotide excision repair. Purified pol II and oligo(dC)-tailed templates containing a single non-bulky DNA lesion on the transcribed strand such as an apurinic/apyrimidinic (AP) site, uracil, or 8-oxoguanine (8-oxoG) were used for transcription elongation assays. In this system pol II could bypass both the AP site and uracil without pausing and insert cytosine opposite the AP site and either guanine or adenine opposite to uracil. Thus, the AP site on the DNA templates could lead to correct transcription only if depurination at guanine occurred, whereas uracil generated either the correct transcriptional product or an incorrect one with a G:C to A:T transition. In the case of 8-oxoG, pol II stalled at the lesion, but sometimes bypassed it and inserted a cytosine residue or the incorrect adenine residue leading to a G:C to T:A transversion. These findings indicate that 8-oxoG lesions caused a blockage of transcription elongation and/or the misincorporation of a ribonucleotide by pol II, implying the initiation of transcription-coupled repair of 8-oxoG and/or transcriptional mutagenesis.

Drosophila S3 ribosomal protein accelerates repair of 8-oxoguanine performed by human and mouse cell extracts

The S3 ribosomal protein of Drosophila melanogaster possesses various DNA repair activities, including the capacity to incise at apurinic/apyrimidinic (AP) sites and 8-oxo-7,8-dihydroguanine (8-oxoG) residues. We have recently hypothesized that this multifunctional protein may improve the efficiency of DNA base excision repair (BER) in mammalian cells. We have investigated the effect of pure GST-tagged Drosophila S3 on BER of different endogenous lesions performed by human and mouse cell extracts. Drosophila S3 significantly accelerated the BER of 8-oxoG (initiated by the bifunctional glycosylase OGG1). The stimulating effect was linked to the capacity of S3 to remove the 8-oxoG lesion and cleave the resulting AP site, rather than acceleration of downstream steps of the BER pathway (e.g., removal of 3' blocking fragments). No stimulating effect was observed on the BER of uracil, natural AP sites, and beta-lyase-cleaved AP sites. Heterologous expression of Drosophila S3 may be used to enhance 8-oxoG repair in human cells.

Protection of DNA by alpha/beta-type small, acid-soluble proteins from Bacillus subtilis spores against cytosine deamination

Spores of Bacillus subtilis contain high levels of proteins, termed alpha/beta-type small, acid-soluble proteins (SASP), that protect the spore's DNA against different types of DNA damage. We tested one such protein, SspC, and two of its variants for their ability to protect plasmid DNA against hydrolytic deamination of cytosine to uracil. If unrepaired, such damage to DNA causes C to T mutations. We found that one SspC variant, SspC(Delta 11-D13K), protected DNA against cytosine deamination at two different temperatures (45 and 70 degrees C) and pH values (5.2 and 7.9), reducing the rate of deamination by as much as 10-fold. At 70 degrees C, pH 7.9, the wild-type SspC and its variant, SspC(Delta 11), provided little protection against deamination but were effective in protecting DNA at 45 degrees C, pH 7.9. Parallel studies of the abilities of these proteins to protect DNA against restriction digestion revealed that there was a good correlation between the abilities of the proteins to protect against restriction endonucleases and reductions in cytosine deaminations. These results show that the binding of SspC variants to DNA can prevent attack on DNA bases by water and suggest a new general mechanism by which DNA-binding proteins in cells may be able to protect chromosomes from endogenous and exogenous reactive chemicals by excluding them from the vicinity of DNA.

Incision of AP sites in lung cancer patients: a pilot study

DNA base excision repair (BER) removes frequent DNA lesions of either endogenous or exogenous origin. Some indications point to BER defects in lung cancer patients. We have investigated the ability of ten lung cancer patients to repair natural AP sites, the most frequent genetic lesion, using an in vitro assay in which peripheral blood lymphocytes (PBL) extracts incise randomly depurinated plasmid DNA. The median value of repair activity in patients was lower than that of matched controls but the difference did not reach significance. Unlike other BER enzymatic steps, marked defects in incision of AP sites may not be associated with lung carcinogenesis.

Homologous DNA recombination in vertebrate cells

The RAD52 epistasis group genes are involved in homologous DNA recombination, and their primary structures are conserved from yeast to humans. Although biochemical studies have suggested that the fundamental mechanism of homologous DNA recombination is conserved from yeast to mammals, recent studies of vertebrate cells deficient in genes of the RAD52 epistasis group reveal that the role of each protein is not necessarily the same as that of the corresponding yeast gene product. This review addresses the roles and mechanisms of homologous recombination-mediated repair with a special emphasis on differences between yeast and vertebrate cells.

DNA replication fidelity

DNA replication fidelity is a key determinant of genome stability and is central to the evolution of species and to the origins of human diseases. Here we review our current understanding of replication fidelity, with emphasis on structural and biochemical studies of DNA polymerases that provide new insights into the importance of hydrogen bonding, base pair geometry, and substrate-induced conformational changes to fidelity. These studies also reveal polymerase interactions with the DNA minor groove at and upstream of the active site that influence nucleotide selectivity, the efficiency of exonucleolytic proofreading, and the rate of forming errors via strand misalignments. We highlight common features that are relevant to the fidelity of any DNA synthesis reaction, and consider why fidelity varies depending on the enzymes, the error, and the local sequence environment.

Reverse genetic studies of homologous DNA recombination using the chicken B-lymphocyte line, DT40

DT40 is an avian leucosis virus-transformed chicken B-lymphocyte line which exhibits high ratios of targeted to random integration of transfected DNA constructs. This efficient targeted integration may be related to the ongoing diversification of the variable segment of the immunoglobulin gene through homologous DNA recombination-controlled gene conversion. DT40s are a convenient model system for making gene-targeted mutants. Another advantage is the relative tractability of these cells, which makes it possible to disrupt multiple genes in a single cell and to generate conditionally gene-targeted mutants including temperature-sensitive mutants. There are strong phenotypic similarities between murine and DT40 mutants of various genes involved in DNA recombination. These similarities confirm that the DT40 cell line is a reasonable model for the analysis of vertebrate DNA recombination, despite obvious concerns associated with the use of a transformed cell line, which may have certain cell-line-specific characteristics. Here we describe our studies of homologous DNA recombination in vertebrate somatic cells using reverse genetics in DT40 cells.

Efficient repair of 8-oxo-7,8-dihydrodeoxyguanosine in human and hamster xeroderma pigmentosum D cells

The repair of the endogenous lesion 8-oxo-7,8-dihydrodeoxyguanosine (8-oxodG) was investigated in the nucleotide excision repair mutant xeroderma pigmentosum D (XPD), using human normal or transformed XPD fibroblasts and the Chinese hamster XPD cell line UV5. In vivo repair of 8-oxodG induced by hydrogen peroxide treatment and analyzed by high-performance liquid chromatography/electrochemical detection was normal in the XPD mutant fibroblasts XP15PV and GM434, as compared to normal human fibroblasts GM970, GM5757, and GM6114. Similar results were obtained with the human SV40-transformed XPD mutant cell line GM8207 in comparison to the control cell line GM637. Repair of 8-oxodG was even slightly (2-3-fold) but reproducibly increased in Chinese hamster XPD mutant UV5 cells, as compared to parental AA8 cells. This unexpected effect was reversed by transfection in UV5 cells of a wild-type XPD cDNA and confirmed in in vitro experiments in which a plasmid substrate containing a single 8-oxoG was repaired by UV5 cell extracts. The data show that repair of 8-oxodG is normal in XPD cells, thus indicating that the neurological complications of XPD patients may not be linked to in vivo accumulation of this lesion.

DNA damage-induced mutation: tolerance via translesion synthesis

Translesion synthesis (TLS) appears to be required for most damage-induced mutagenesis in the yeast Saccharomyces cerevisiae, whether the damage arises from endogenous or exogenous sources. Thus, the production of such mutations seems to occur primarily as a consequence of the tolerance of DNA lesions rather than an error-prone repair mechanism. Tolerance via TLS in yeast involves proteins encoded by members of the RAD6 epistasis group for the repair of ultraviolet (UV) photoproducts, in particular two non-essential DNA polymerases that catalyse error-free or error-prone TLS. Homologues of these RAD6 group proteins have recently been discovered in rodent and/or human cells. Furthermore, the operation of error-free TLS in humans has been linked to a reduced risk of UV-induced skin cancer, whereas mutations generated by error-prone TLS may increase the risk of cancer. In this article, we review and link the evidence for translesion synthesis in yeast, and the involvement of nonreplicative DNA polymerases, to recent findings in mammalian cells.

Overexpression of enzymes that repair endogenous damage to DNA

A significant contribution to human mutagenesis and carcinogenesis may come from DNA damage of endogenous, rather than exogenous, origin. Efficient repair mechanisms have evolved to cope with this. The main repair pathway involved in repair of endogenous damage is DNA base excision repair. In addition, an important contribution is given by O6-alkylguanine DNA alkyltranferase, that repairs specifically the miscoding base O6-alkylguanine. In recent years, several attempts have been carried out to enhance the efficiency of repair of endogenous damage by overexpressing in mammalian cells single enzymatic activities. In some cases (e.g. O6-alkylguanine DNA alkyltransferase or yeast AP endonuclease) this approach has been successful in improving cellular protection from endogenous and exogenous mutagens, while overexpression of other enzymatic activities (e.g. alkyl N-purine glycosylase or DNA polymerase beta) were detrimental and even produced a genome instability phenotype. The reasons for these different outcomes are analyzed and alternative enzymatic activities whose overexpression may improve the efficiency of repair of endogenous damage in human cells are proposed.