A deoxyribozyme with a novel guanine quartet-helix pseudoknot structure

Here we report a deoxyribozyme with a unique structure that contains a two-tiered guanine quadruplex interlinked to a Watson-Crick duplex. Through in vitro selection, sequence mutation, and methylation interference, we show the presence of both the two-tiered guanine-quadruplex and two helical regions contained in the active structure of this self-phosphorylating deoxyribozyme. Interestingly, one GG element of the quadruplex is part of a hairpin loop within one of the identified helical regions. Circular dichroism analysis showed that antiparallel quadruplex formation was dependent on this helix. To our knowledge, this is the first report of a pseudoknot nucleic acid structure that involves a guanine quadruplex. Our findings indicate that guanine quadruplexes can be part of complex structural arrangements, increasing the likelihood of finding more complex guanine quadruplex arrangements in biological systems.     

A Deoxyribozyme, Sero1C, Uses Light and Serotonin to Repair Diverse Pyrimidine Dimers in DNA

An in vitro selection search for DNAs capable of catalyzing photochemistry yielded two distinctive deoxyribozymes (DNAzymes) with photolyase activity: UV1C, which repaired thymine dimers within DNA using a UV light of > 300 nm wavelength and no extraneous cofactor, and Sero1C, which required the tryptophan metabolite serotonin as cofactor in addition to the UV light. Catalysis by Sero1C conformed to Michaelis-Menten kinetics, and analysis of the action spectrum of Sero1C confirmed that serotonin did indeed serve as a catalytic cofactor rather than as a structural cofactor. Sero1C and UV1C showed strikingly distinct wavelength optima for their respective photoreactivation catalyses. Although the rate enhancements characteristic of the two DNAzymes were similar, the cofactor-requiring Sero1C repaired a substantially broader range of substrates compared to UV1C, including thymine, uracil, and a range of chimeric deoxypyrimidine and ribopyrimidine dimers. Similarities and differences in the properties of these two photolyase DNAzymes suggest, first, that the harnessing of less damaging UV light for the repair of photolesions may have been a primordial catalytic activity of nucleic acids, and, second, the broader substrate range of Sero1C may highlight an evolutionary advantage to coopting amino-acid-like cofactors by functionality-poor nucleic acid enzymes.     

Human mitochondrial DNA polymerase γ exhibits potential for bypass and mutagenesis at UV-induced cyclobutane thymine dimers

Cyclobutane thymine dimers (T-T) comprise the majority of DNA damage caused by short wavelength ultraviolet radiation. These lesions generally block replicative DNA polymerases and are repaired by nucleotide excision repair or bypassed by translesion polymerases in the nucleus. Mitochondria lack nucleotide excision repair, and therefore, it is important to understand how the sole mitochondrial DNA polymerase, pol γ, interacts with irreparable lesions such as T-T. We performed in vitro DNA polymerization assays to measure the kinetics of incorporation opposite the lesion and bypass of the lesion by pol γ with a dimer-containing template. Exonuclease-deficient pol γ bypassed thymine dimers with low relative efficiency; bypass was attenuated but still detectable when using exonuclease-proficient pol γ. When bypass did occur, pol γ misincorporated a guanine residue opposite the 3'-thymine of the dimer only 4-fold less efficiently than it incorporated an adenine. Surprisingly, the pol γ exonuclease-proficient enzyme excised the incorrectly incorporated guanine at similar rates irrespective of the nature of the thymines in the template. In the presence of all four dNTPs, pol γ extended the primer after incorporation of two adenines opposite the lesion with relatively higher efficiency compared with extension past either an adenine or a guanine incorporated opposite the 3'-thymine of the T-T. Our results suggest that T-T usually stalls mitochondrial DNA replication but also suggest a mechanism for the introduction of point mutations and deletions in the mitochondrial genomes of chronically UV-exposed cells.     

Effects of temperature on the photoreactivation of ultraviolet-b–induced dna damage in Palmaria palmata (Rhodophyta)

The accumulation of DNA damage (thymine dimers and 6-4 photoproducts) induced by ultraviolet-B radiation was studied in Palmaria palmata (L.) O. Kuntze under different light and temperature conditions, using specific monoclonal antibodies and subsequent chemiluminescent detection. Both types of damage were repaired much faster under ultraviolet-A radiation (UVAR) plus photosynthetically active radiation (PAR) than in darkness, which indicates photoreactivating activity. At 12° C, all thymine dimers were repaired after 2 h irradiation with UVAR plus PAR, whereas 6-4 photoproducts were almost completely repaired after 4 h. After 19 h of darkness, almost complete repair of 6-4 photoproducts was found, and 67% of the thymine dimers were repaired. In a second set of experiments, repair of DNA damage under UVAR plus PAR was compared at three different temperatures (0, 12, and 25° C). Again, thymine dimers were repaired faster than 6-4 photoproducts at all three temperatures. At 0° C, significant repair of thymine dimers was found but not of 6-4 photoproducts. Significant repair of both thymine dimers and 6-4 photoproducts occurred at 12 and 25° C. Optimal repair efficiency was found at 25° C for thymine dimers but at 12° C for 6-4 photoproducts, which suggests that the two photorepair processes have different temperature characteristics.     

The interplay of supercoiling and thymine dimers in DNA

Thymine dimers are a major mutagenic photoproduct induced by UV radiation. While they have been the subject of extensive theoretical and experimental investigations, questions of how DNA supercoiling affects local defect properties, or, conversely, how the presence of such defects changes global supercoiled structure, are largely unexplored. Here, we introduce a model of thymine dimers in the oxDNA forcefield, parametrized by comparison to melting experiments and structural measurements of the thymine dimer induced bend angle. We performed extensive molecular dynamics simulations of double-stranded DNA as a function of external twist and force. Compared to undamaged DNA, the presence of a thymine dimer lowers the supercoiling densities at which plectonemes and bubbles occur. For biologically relevant supercoiling densities and forces, thymine dimers can preferentially segregate to the tips of the plectonemes, where they enhance the probability of a localized tip-bubble. This mechanism increases the probability of highly bent and denatured states at the thymine dimer site, which may facilitate repair enzyme binding. Thymine dimer-induced tip-bubbles also pin plectonemes, which may help repair enzymes to locate damage. We hypothesize that the interplay of supercoiling and local defects plays an important role for a wider set of DNA damage repair systems.     

Role of base flipping in specific recognition of damaged DNA by repair enzymes

DNA repair enzymes induce base flipping in the process of damage recognition. Endonuclease V initiates the repair of cis, syn thymine dimers (TD) produced in DNA by UV radiation. The enzyme is known to flip the base opposite the damage into a non-specific binding pocket inside the protein. Uracil DNA glycosylase removes a uracil base from G.U mismatches in DNA by initially flipping it into a highly specific pocket in the enzyme. The contribution of base flipping to specific recognition has been studied by molecular dynamics simulations on the closed and open states of undamaged and damaged models of DNA. Analysis of the distributions of bending and opening angles indicates that enhanced base flipping originates in increased flexibility of the damaged DNA and the lowering of the energy difference between the closed and open states. The increased flexibility of the damaged DNA gives rise to a DNA more susceptible to distortions induced by the enzyme, which lowers the barrier for base flipping. The free energy profile of the base-flipping process was constructed using a potential of mean force representation. The barrier for TD-containing DNA is 2.5 kcal mol(-1) lower than that in the undamaged DNA, while the barrier for uracil flipping is 11.6 kcal mol(-1) lower than the barrier for flipping a cytosine base in the undamaged DNA. The final barriers for base flipping are approximately 10 kcal mol(-1), making the rate of base flipping similar to the rate of linear scanning of proteins on DNA. These results suggest that damage recognition based on lowering the barrier for base flipping can provide a general mechanism for other DNA-repair enzymes.     

Effect of a modified thymine on the structure and stability of [d(TGGGT)]4 quadruplex

Telomeric guanine-rich sequence can adopt quadruplex structures that are important for their biological role in chromosomal stabilisation. G quartets are characterised by the cyclic hydrogen bonding of four guanine bases in a coplanar arrangement and their stability is ion-dependent. In this work we compare the stability of [d(TGGGT)]₄ and [d(T*GGGT)]₄ quadruplexes. The last one contains a modified thymine, where the hydroxyl group substitutes one hydrogen atom of the methyl group of the thymine in the [d(TGGGT)]₄ sequence. We used a combination of spectroscopic, calorimetric and computational techniques to characterise the G-quadruplex formation. NMR and CD spectra of [d(T*GGGT)]₄ were characteristic of parallel-stranded, tetramolecular quadruplex. CD and DSC melting experiments reveal that [d(T*GGGT)]₄ is less stable that unmodified quadruplex. Molecular models suggest possible explanation for the observed behaviour.     

No detectable DNA excision repair in UV-exposed hepatocytes from two catfish species

DNA repair is a critical process in protecting cellular genetic information from mutation. Nucleotide excision repair (NER) is a mechanism by which cells correct DNA damage caused by agents that form bulky covalent adducts and UV photoproducts such as thymine dimers and 6-4 photoproduct. NER, sometimes called dark repair, is generally accepted as being low in fish compared to mammals. This study was designed to quantitate NER in two related catfish species that have known differential sensitivities to liver carcinomas. The original hypothesis was that the more cancer resistant species, channel catfish (Ictalurus punctatus), would have more efficient DNA repair compared to the more sensitive brown bullhead (Ameriurus nebulosus). In order to measure NER, primary cultured hepatocytes of both species were exposed to UV light (10-40 J/m2) and collected at 0, 24, 48 and 72 h after exposure. Total DNA was extracted from the cells and incubated with T4 endonuclease V. Using alkaline gel electrophoresis, endonuclease sensitive sites (ESS) were quantified. Results from the ESS assay indicated there was a UV dose-response increase in thymine dimers from 0 to 40 J/m2. However, no repair (decrease in number of ESS) occurred in either fish species over a 72-h time period. When cells were exposed to photoreactivating fluorescent light, repair was detected. These studies highlight the difficulty of measuring NER in fish and are consistent with the low levels of NER reported by other researchers in fish.     

UV damage to plant life in a photobiologically dynamic environment: the case of marine phytoplankton

The effect of UV-B radiation on growth of marine phytoplankton was investigated in relation to DNA damage induced by a range of biologically effective doses (BEDs). Emiliania huxleyi (Prymnesiophyceae) was chosen as a model organism of the ocean's phytoplankton because of its importance in global biogeochemical cycling of carbon and sulphur, elements that influence the world's climate as components of the trace gases carbon dioxide (CO₂) and dimethylsulfide (DMS). A marine diatom, Cyclotella, was studied for its capacity to repair the DNA damage, quantified as thymine dimers by the application of a monoclonal antibody against these photoproducts. DNA repair was shown to be complete after just a few hours of exposure to visible light; the repair rate increased with PAR intensity. E. huxleyi appeared to be most sensitive to UV-B radiation: growth was already affected above a dose of 100 J m^-2 d^-1 (biologically effective radiation, weighted with Setlow's DNA action spectrum), probably through effects on the cell cycle related to damage to nuclear DNA: mean specific growth rates were inversely correlated with thymine dimer contents in cells. Near the ocean's surface UV-B radiation conditions that induce the changes observed by us in cultures can be expected during the growing season of phytoplankton, not only in the tropics but also at higher latitudes. Nevertheles, blooms of species such as E. huxleyi are often excessive in the field. It is suggested that exposure duration of cells near the surface of the ocean can be shorter than our artificial 3 h in the laboratory due to vertical mixing, a phenomenon that is typical for the ocean's upper 50–100 m. When mixing reaches depths greater than the layer where most UV-B is attenuated, negative effects on cells through UV-A-induced inhibition of photosynthesis may prevail over DNA damage, the action spectrum of which has been shown to be limited to the UV-B part of the spectrum. Moreover, the radiation wavelengths that induce DNA damage repair (UV-A and visible) are attenuated vertically much less than UV-B. The photobiological situation in the upper ocean is much more complicated than on land, and effects of UV radiation on plankton biota can only be modelled realistically here when both the spectrally differential attenuation in the UV and visual part of the spectrum and the rate of vertical mixing are taken into account. Action spectra of both damage and repair of DNA and of photosynthesis inhibition of representative microalgal species are the second conditio sine qua non if we want to predict the effect of stratospheric ozone depletion on marine phytoplankton performance.     

Structure of T4 pyrimidine dimer glycosylase in a reduced imine covalent complex with abasic site-containing DNA

The base excision repair (BER) pathway for ultraviolet light (UV)-induced cyclobutane pyrimidine dimers is initiated by DNA glycosylases that also possess abasic (AP) site lyase activity. The prototypical enzyme known to catalyze these reactions is the T4 pyrimidine dimer glycosylase (T4-Pdg). The fundamental chemical reactions and the critical amino acids that lead to both glycosyl and phosphodiester bond scission are known. Catalysis proceeds via a protonated imine covalent intermediate between the alpha-amino group of the N-terminal threonine residue and the C1' of the deoxyribose sugar of the 5' pyrimidine at the dimer site. This covalent complex can be trapped as an irreversible, reduced cross-linked DNA-protein complex by incubation with a strong reducing agent. This active site trapping reaction is equally efficient on DNA substrates containing pyrimidine dimers or AP sites. Herein, we report the co-crystal structure of T4-Pdg as a reduced covalent complex with an AP site-containing duplex oligodeoxynucleotide. This high-resolution structure reveals essential precatalytic and catalytic features, including flipping of the nucleotide opposite the AP site, a sharp kink (approximately 66 degrees ) in the DNA at the dimer site and the covalent bond linking the enzyme to the DNA. Superposition of this structure with a previously published co-crystal structure of a catalytically incompetent mutant of T4-Pdg with cyclobutane dimer-containing DNA reveals new insights into the structural requirements and the mechanisms involved in DNA bending, nucleotide flipping and catalytic reaction.     

The kinetics of thymine dimer excision in ultraviolet-irradiated human cells

We have investigated the kinetics of the loss of thymine dimers from the acid-insoluble fraction of several ultraviolet (UV)-irradiated cultured human cell lines. Our results show that UV fluences between 10 and 40 J/m2 produce an average of 21-85 x 10(5) thymine dimers per cell and an eventual maximal loss per cell of 12-20 x 10(5) thymine dimers. The time for half-maximal loss of dimers ranged from 12-22 h after UV irradiation. In contrast, the time for half-maximal repair synthesis of DNA measured by autoradiography was 4.5 h. This figure agrees well with reported half-maximal repair synthesis times, which range from 0.5 to 3.6 h based on our analysis. The discrepancy in the kinetics of the loss of thymine dimers from DNA and repair synthesis is discussed in terms of possible molecular mechanisms of thymine dimer excision in vivo and in terms of possible experimental artifacts.     

Spore photoproduct within DNA is a surprisingly poor substrate for its designated repair enzyme—The spore photoproduct lyase

DNA repair enzymes typically recognize their substrate lesions with high affinity to ensure efficient lesion repair. In UV irradiated endospores, a special thymine dimer, 5-thyminyl-5,6-dihydrothymine, termed the spore photoproduct (SP), is the dominant DNA photolesion, which is rapidly repaired during spore outgrowth mainly by spore photoproduct lyase (SPL) using an unprecedented protein-harbored radical transfer process. Surprisingly, our in vitro studies using SP-containing short oligonucleotides, pUC 18 plasmid DNA, and E. coli genomic DNA found that they are all poor substrates for SPL in general, exhibiting turnover numbers of 0.01–0.2 min⁻¹. The faster turnover numbers are reached under single turnover conditions, and SPL activity is low with oligonucleotide substrates at higher concentrations. Moreover, SP-containing oligonucleotides do not go past one turnover. In contrast, the dinucleotide SP TpT exhibits a turnover number of 0.3–0.4 min⁻¹, and the reaction may reach up to 10 turnovers. These observations distinguish SPL from other specialized DNA repair enzymes. To the best of our knowledge, SPL represents an unprecedented example of a major DNA repair enzyme that cannot effectively repair its substrate lesion within the normal DNA conformation adopted in growing cells. Factors such as other DNA binding proteins, helicases or an altered DNA conformation may cooperate with SPL to enable efficient SP repair in germinating spores. Therefore, both SP formation and SP repair are likely to be tightly controlled by the unique cellular environment in dormant and outgrowing spore-forming bacteria, and thus SP repair may be extremely slow in non-spore-forming organisms.     

Effect of base, pentose, and phosphodiester backbone structures on binding and repair of pyrimidine dimers by Escherichia coli DNA photolyase.

Photolyases reverse the effects of UV light on cells by converting cyclobutane dipyrimidine photoproducts (pyrimidine dimers, Pyr mean value of Pyr) into pyrimidine monomers in a light-dependent reaction. Previous work has suggested that, based on substrate preference, there are two classes of photolyase: DNA photolyase as exemplified by the Escherichia coli enzyme, and RNA photolyases found in plants such as Nicotiana tabacum and Phaseolus vulgaris. In experiments aimed at identifying substrate determinants, including the pentose ring, for binding and catalysis by E. coli DNA photolyase we tested several Pyr mean value of Pyr. We found that the enzyme has relative affinities for photodimers of T mean value of T greater than or equal to U mean value of T greater than U mean value of U much greater than C mean value of C and that the E-FADH2 form of the enzyme repairs these dimers at 366 nm with absolute quantum yields of 0.9 (T mean value of T), 0.8 (U mean value of T), 0.6 (U mean value of U), and 0.05 (C mean value of C). The enzyme also repairs an isolated thymine dimer and the synthetic substrate, 1,1'-trimethylene-bis (thymine) cyclobutane dimer. Unexpectedly, we found that this enzyme, previously thought to be specific for DNA, repairs uracil cyclobutane dimers in poly(rU). The affinity of photolyase for a uracil dimer in RNA is about 10(4)-fold lower than that for a U mean value of U in DNA; however, once bound, the enzyme repairs the photodimer with the same quantum yield whether the dimer is in ribonucleoside or deoxyribonucleoside form.     

Immuno-capture of UVDE generated 3’-OH ends at UV photoproducts

A strategy amenable to the genome-wide study of DNA damage and repair kinetics is described. The ultraviolet damage endonuclease (UVDE) generates 3’-OH ends at the two major UV induced DNA lesions, cyclobutane pyrimidine dimers (CPDs) and 6,4 pyrimidine-pyrimidone dimers (6,4 PPs), allowing for their capture after biotin end-labeling. qPCR amplification of biotinylated DNA enables parallel measuring of DNA damage in several loci, which can then be combined with high-throughput screening of cell survival to test genotoxic reagents. Alternatively, a library of captured sequences could be generated for a genome wide study of damage sites and large-scale assessment of repair kinetics in different regions of the genome, using next-generation sequencing. The assay is suitable to study any DNA lesion that can be converted into 3’-OH by UVDE, or other enzymes. Toward these goals, we compared UVDE with the classical T4 endonuclease V (T4V) assay. We showed that there is a linear correlation between UV dose, 3’-OH formation and capture by immunoprecipitation, together with its potential application for in vivo studies.     

Human thymine DNA glycosylase (TDG) and methyl-CpG-binding protein 4 (MBD4) excise thymine glycol (Tg) from a Tg:G mispair

The repair enzymes thymine DNA glycosylase (TDG) and methyl-CpG-binding protein 4 (MBD4) remove thymines from T:G mismatches resulting from deamination of 5-methylcytosine. Thymine glycol, a common DNA lesion produced by oxidative stress, can arise from oxidation of thymine or from oxidative deamination of 5-methylcytosine, and is then present opposite adenine or opposite guanine, respectively. Here we have used oligonucleotides with thymine glycol incorporated into different sequence contexts and paired with adenine or guanine. We show that TDG and MBD4 can remove thymine glycol when present opposite guanine but not when paired with adenine. The efficiency of these enzymes for removal of thymine glycol is about half of that for removal of thymine in the same sequence context. The two proteins may have evolved to act specifically on DNA mismatches produced by deamination and by oxidation-coupled deamination of 5-methylcytosine. This repair pathway contributes to mutation avoidance at methylated CpG dinucleotides.     

Site-specific repair of cyclobutane pyrimidine dimers in a positioned nucleosome by photolyase and T4 endonuclease V in vitro.

Since genomic DNA is folded into nucleosomes, and DNA damage is generated all over the genome, a central question is how DNA repair enzymes access DNA lesions and how they cope with nucleosomes. To investigate this topic, we used a reconstituted nucleosome (HISAT nucleosome) as a substrate to generate DNA lesions by UV light (cyclobutane pyrimidine dimers, CPDs), and DNA photolyase and T4 endonuclease V (T4-endoV) as repair enzymes. The HISAT nucleosome is positioned precisely and contains a long polypyrimidine region which allows one to monitor formation and repair of CPDs over three helical turns. Repair by photolyase and T4-endoV was inefficient in nucleosomes compared with repair in naked DNA. However, both enzymes showed a pronounced site-specific modulation of repair on the nucleosome surface. Removal of the histone tails did not substantially enhance repair efficiency nor alter the site specificity of repair. Although photolyase and T4-endoV are different enzymes with different mechanisms, they exhibited a similar site specificity in nucleosomes. This implies that the nucleosome structure has a decisive role in DNA repair by exerting a strong constraint on damage accessibility. These findings may serve as a model for damage recognition and repair by more complex repair mechanisms in chromatin.     

Effect of Thymine Starvation on Deoxyribonucleic Acid Repair Systems of Escherichia coli K-12

Thymine starvation of Escherichia coli K-12 results in greatly increased sensitivity to ultraviolet light (UV). Our studies, using isogenic strains carrying rec and uvr mutations, have shown the following. (i) Common to all strains tested is a change from multihit to single-hit kinetics of survival to UV after 60 min of thymine starvation. However, the limiting slope of UV survival curves decreases in the rec(+)uvr(+) strain and changes very little in several rec mutant strains and one uvrB mutant strain. Thus, when either the rec or uvr system is functioning alone, the limiting slopes of the UV survival curves are relatively unaffected by thymine starvation. (ii) Thymine starvation does not significantly inhibit repair processes carried out by either repair system alone; i.e., host cell reactivation of irradiated phage (carried out by the uvr system), excision of thymine dimers (uvr), or X-ray repair (rec). (iii) In a rec(+)uvr(+) strain, repair appears to be a synergistic rather than additive function of the two systems. However, after thymine starvation, repair capacity is reduced to about the sum of the repair capacities of the independent systems. (iv) The kinetics of thymineless death are not changed by rec and uvr mutations. This indicates that the lesions responsible for thymineless death are not repaired by rec or uvr systems. (v) Withholding thymine from thy rec(+)uvr(+) bacteria not undergoing thymineless death has no effect on UV sensitivity. Under these conditions one sees higher than normal UV resistance in the presence or absence of thymine. This is due to increased repair carried out by the uvr system. To explain these results we postulate that thymine starvation does not inhibit either the rec or uvr repair pathway directly. Rather it appears that thymine starvation results in increased UV sensitivity in part by inhibiting a function which normally carries out efficient coordination of rec and uvr pathways.