Dihydrothymidine and thymidine glycol triphosphates as substrates for DNA polymerases: differential recognition of thymine C5-C6 bond saturation and sequence specificity of incorporation

Clustered DNA Damage and its Complexity: Tracking the History

The concept of radiation-induced clustered damage in DNA has grown over the past several decades to become a topic of considerable interest across the scientific disciplines involved in studies of the biological effects of ionizing radiation. This paper, prepared for the 70th anniversary issue of Radiation Research, traces historical development of the three main threads of physics, chemistry, and biochemical/cellular responses that led to the hypothesis and demonstration that a key component of the biological effectiveness of ionizing radiation is its characteristic of producing clustered DNA damage of varying complexities. The physics thread has roots that started as early as the 1920s, grew to identify critical nanometre-scale clusterings of ionizations relevant to biological effectiveness, and then, by the turn of the century, had produced an extensive array of quantitative predictions on the complexity of clustered DNA damage from different radiations. Monte Carlo track structure simulation techniques played a key role through these developments, and they are now incorporated into many recent and ongoing studies modelling the effects of radiation. The chemistry thread was seeded by water-radiolysis descriptions of events in water as radical-containing "spurs," demonstration of the important role of the hydroxyl radical in radiation-inactivation of cells and the difficulty of protection by radical scavengers. This led to the concept and description of locally multiply damaged sites (LMDS) for DNA double-strand breaks and other combinations of DNA base damage and strand breakage that could arise from a spur overlapping, or created in very close proximity to, the DNA. In these ways, both the physics and the chemistry threads, largely in parallel, put out the challenge to the experimental research community to verify these predictions of clustered DNA damage from ionizing radiations and to investigate their relevance to DNA repair and subsequent cellular effects. The third thread, biochemical and cell-based research, responded strongly to the challenge by demonstrating the existence and biological importance of clustered DNA damage. Investigations have included repair of a wide variety of defined constructs of clustered damage, evaluation of mutagenic consequences, identification of clustered base-damage within irradiated cells, and identification of co-localization of repair complexes indicative of complex clustered damage after high-LET irradiation, as well as extensive studies of the repair pathways involved in repair of simple double-strand breaks. There remains, however, a great deal more to be learned because of the diversity of clustered DNA damage and of the biological responses.

α-Tocopherol phosphate as a photosensitizer in the reaction of nucleosides with UV light: formation of 5,6-dihydrothymidine

Introduction

α-Tocopherol phosphate, a natural water-soluble α-tocopherol analog, exists in biological tissues and fluids. Synthesized α-tocopherol phosphate is used as an ingredient of cosmetics.

Findings

When a neutral mixed solution of 2′-deoxycytidine, 2′-deoxyguanosine, thymidine, and 2′-deoxyadenosine was irradiated with UV light at wavelengths longer than 300 nm in the presence of α-tocopherol phosphate, thymidine was markedly consumed in an α-tocopherol phosphate dose-dependent manner, whereas other nucleosides only slightly decreased. Two major product peaks were detected in an HPLC chromatogram. The products were identified as diastereomers of 5,6-dihydrothymidine. The addition of radical scavengers had almost no effects on the generation of 5,6-dihydrothymidine, whereas the reactions of nucleosides other than thymidine were suppressed. Trolox, another water-soluble α-tocopherol analog, did not generate 5,6-dihydrothymidine, although all nucleosides were slightly consumed. When UV irradiation of thymidine with α-tocopherol phosphate was conducted in D₂O, two deuterium atoms were added to 5 and 6 positions of thymidine with both syn and anti configurations. The ratio of syn and anti configurations alternated depending on pD of the solution.

Conclusions

The results indicate that α-tocopherol phosphate is a photosensitizer of nucleosides, especially thymidine, and that it introduces two hydrogen atoms to thymidine from H₂O, generating 5,6-dihydrothymidine.

Consequences and repair of radiation-induced DNA damage: fifty years of fun questions and answers

PURPOSE

To summarize succinctly the 50 years of research undertaken in my laboratory and to provide an overview of my career in science. It is certainly a privilege to have been asked by Carmel Mothersill and Penny Jeggo to contribute to this special issue of the International Journal of Radiation Biology focusing on the work of women in the radiation sciences.

CONCLUSION

My students, post-docs and I identified and characterized a number of the enzymes that recognize and remove radiation-damaged DNA bases, the DNA glycosylases, which are the first enzymes in the Base Excision Repair (BER) pathway. Although this pathway actually evolved to repair oxidative and other endogenous DNA damages, it is also responsible for removing the vast majority of radiation-induced DNA damages including base damages, alkali-labile lesions and single strand breaks. However, because of its high efficiency, attempted BER of clustered lesions produced by ionizing radiation, can have disastrous effects on cellular DNA. We also evaluated the potential biological consequences of many of the radiation-induced DNA lesions. In addition, with collaborators, we employed computational techniques, x-ray crystallography and single molecule approaches to answer many questions at the molecular level.

Dihydropyrimidine accumulation is required for the epithelial-mesenchymal transition

It is increasingly appreciated that oncogenic transformation alters cellular metabolism to facilitate cell proliferation, but less is known about the metabolic changes that promote cancer cell aggressiveness. Here, we analyzed metabolic gene expression in cancer cell lines and found that a set of high-grade carcinoma lines expressing mesenchymal markers share a unique 44 gene signature, designated the "mesenchymal metabolic signature" (MMS). A FACS-based shRNA screen identified several MMS genes as essential for the epithelial-mesenchymal transition (EMT), but not for cell proliferation. Dihydropyrimidine dehydrogenase (DPYD), a pyrimidine-degrading enzyme, was highly expressed upon EMT induction and was necessary for cells to acquire mesenchymal characteristics in vitro and for tumorigenic cells to extravasate into the mouse lung. This role of DPYD was mediated through its catalytic activity and enzymatic products, the dihydropyrimidines. Thus, we identify metabolic processes essential for the EMT, a program associated with the acquisition of metastatic and aggressive cancer cell traits.

Thymidine glycol: the effect on DNA molecular structure and enzymatic processing

Thymine glycol (Tg) in DNA is a biologically active oxidative damage caused by ionizing radiation or oxidative stress. Due to chirality of C5 and C6 atoms, Tg exists as a mixture of two pairs of cis and trans diastereomers: 5R cis-trans pair (5R,6S; 5R,6R) and 5S cis-trans pair (5S,6R; 5S,6S). Of all the modified pyrimidine lesions that have been studied to date, only thymine glycol represents a strong block to high-fidelity DNA polymerases in vitro and is lethal in vivo. Here we describe the preparation of thymine glycol-containing oligonucleotides and the influence of the oxidized residue on the structure of DNA in different sequence contexts, thymine glycol being paired with either adenine or guanine. The effect of thymine glycol on biochemical processing of DNA, such as biosynthesis, transcription and repair in vitro and in vivo, is also reviewed. Special attention is paid to stereochemistry and 5R cis-trans epimerization of Tg, and their relation to the structure of DNA double helix and enzyme-mediated DNA processing. Described here are the comparative structure and properties of other forms of pyrimidine base oxidation, as well as the role of Tg in tandem lesions.

Human DNA polymerase kappa bypasses and extends beyond thymine glycols during translesion synthesis in vitro, preferentially incorporating correct nucleotides

Human polymerase kappa (polkappa), the product of the human POLK (DINB1) gene, is a member of the Y superfamily of DNA polymerases that support replicative bypass of chemically modified DNA bases (Ohmori, H., Friedberg, E. C., Fuchs, R. P., Goodman, M. F., Hanaoka, F., Hinkle, D., Kunkel, T. A., Lawrence, C. W., Livneh, Z., Nohmi, T., Prakash, L., Prakash, S., Todo, T., Walker, G. C., Wang, Z., and Woodgate, R. (2001) Mol. Cell 8, 7-8; Gerlach, V. L., Aravind, L., Gotway, G., Schultz, R. A., Koonin, E. V., and Friedberg, E. C. (1999) Proc. Natl. Acad. Sci. U. S. A. 96, 11922-11927). Polkappa is shown here to bypass 5,6-dihydro-5,6-dihydroxythymine (thymine glycol) generated in two different DNA substrate preparations. Polkappa inserts the correct base adenine opposite thymine glycol in preference to the other three bases. Additionally, the enzyme correctly extends beyond the site of the thymine glycol lesion when presented with adenine opposite thymine glycol at the primer terminus. However, steady state kinetic analysis of nucleotides incorporated opposite thymine glycol demonstrates different misincorporation rates for guanine with each of the two DNA substrates. The two substrates differ only in the relative proportions of thymine glycol stereoisomers, suggesting that polkappa distinguishes among stereoisomers and exhibits reduced discrimination between purines when incorporating a base opposite a 5R thymine glycol stereoisomer. When extending beyond the site of the lesion, the misincorporation rate of polkappa for each of the three incorrect nucleotides (adenine, guanine, and thymine) is dramatically increased. Our findings suggest a role for polkappa in both nonmutagenic and mutagenic bypass of oxidative damage.

DNA substrates containing defined oxidative base lesions and their application to study substrate specificities of base excision repair enzymes

Reactive oxygen species generate structurally diverse base lesions in DNA. These lesions are primarily removed by base excision repair (BER) enzymes in prokaryotic and eukaryotic cells. Biochemical properties of BER enzymes such as substrate specificity, enzymatic parameters, and action mechanisms can be best studied by employing defined oligonucleotide and DNA substrates. Currently available methods are listed to prepare defined DNA substrates containing oxidative base damage and analogs. BER enzymes for oxidative base damage are classified into two subgroups that recognize pyrimidine lesions (Endo III homologs) and purine lesions (Fpg homologs), though E. coli Fpg exhibits weak repair activity for certain pyrimidine damage. Recently, several interesting findings have been reported in relation to the substrate specificity of BER enzymes. Saccharomyces cerevisiae Endo III homologs (NTG1 and NTG2) have been shown to recognize formamidopyrimidine (Fapy) lesions that are derived from purine. Endo III and Endo VIII have a very weak activity to dihydrothymine in comparison with thymine glycol. Excision of 7,8-dihydro-8-oxoguanine by Fpg and human OGG1 is paired-base-dependent, whereas that of Fapy is essentially paired-base-independent. The repair efficiency of BER enzymes is affected by surrounding sequence contexts. In general, the sequence context effect appears to be more pronounced for Fpg homologs than Endo III homologs.

Oxidation of thymine to 5-formyluracil in DNA promotes misincorporation of dGMP and subsequent elongation of a mismatched primer terminus by DNA polymerase

5-Formyluracil (fU) is a major oxidative thymine lesion generated by ionizing radiation and reactive oxygen species. In the present study, we have assessed the influence of fU on DNA replication to elucidate its genotoxic potential. Oligonucleotide templates containing fU at defined sites were replicated in vitro by Escherichia coli DNA polymerase I Klenow fragment deficient in 3'-5'-exonuclease. Gel electrophoretic analysis of the reaction products showed that fU constituted very weak replication blocks to DNA synthesis, suggesting a weak to negligible cytotoxic effect of this lesion. However, primer extension assays with a single dNTP revealed that fU directed incorporation of not only correct dAMP but also incorrect dGMP, although much less efficiently. No incorporation of dCMP and dTMP was observed. When fU was substituted for T in templates, the incorporation efficiency of dAMP (f(A) = V(max)/K(m)) decreased to (1/4) to (1/2), depending on the nearest neighbor base pair, and that of dGMP (f(G)) increased 1.1-5.6-fold. Thus, the increase in the replication error frequency (f(G)/f(A) for fU versus T) was 3.1-14.3-fold. The misincorporation rate of dGMP opposite fU (pK(a) = 8.6) but not T (pK(a) = 10.0) increased with pH (7.2-8.6) of the reaction mixture, indicating the participation of the ionized (or enolate) form of fU in the mispairing with G. The resulting mismatched fU:G primer terminus was more efficiently extended than the T:G terminus (8.2-11.3-fold). These results show that when T is oxidized to fU in DNA, fU promotes both misincorporation of dGMP at this site and subsequent elongation of the mismatched primer, hence potentially mutagenic.

A novel role for Escherichia coli endonuclease VIII in prevention of spontaneous G-->T transversions

In the bacterium Escherichia coli, oxidized pyrimidines are removed by two DNA glycosylases, endonuclease III and endonuclease VIII (endo VIII), encoded by the nth and nei genes, respectively. Double mutants lacking both of these activities exhibit a high spontaneous mutation frequency, and here we show that all of the mutations observed in the double mutants were G:C-->A:T transitions; no thymine mutations were found. These findings are in agreement with the preponderance of C-->T transitions in the oxidative and spontaneous mutational databases. The major oxidized purine lesion in DNA, 7,8-dihydro-8-oxoguanine (8-oxoG), is processed by two DNA glycosylases, formamidopyrimidine DNA glycosylase (Fpg), which removes 8-oxoG opposite C, and MutY DNA glycosylase, which removes misincorporated A opposite 8-oxoG. The high spontaneous mutation frequency previously observed in fpg mutY double mutants was significantly enhanced by the addition of the nei mutation, suggesting an overlap in the substrate specificities between endo VIII and Fpg/MutY. When the mutational specificity was examined, all of the mutations observed were G:C-->T:A transversions, indicating that in the absence of Fpg and MutY, endo VIII serves as a backup activity to remove 8-oxoG. This was confirmed by showing that, indeed, endo VIII can recognize 8-oxoG in vitro.

Solid phase-supported thymine dimers for the construction of dimer-containing DNA by combined chemical and enzymatic synthesis: a potentially general method for the efficient incorporation of modified nucleotides into DNA

The ability to study the structure-activity relationships of the cis-syn thymine dimer, the major photoproduct of DNA, has been greatly aided by the availability of a building block suitable for its sequence-specific incorporation into oligonucleotides by standard automated DNA synthesis. Unfortunately, its usefulness is compromised by the fact that it takes six steps to synthesize in low overall yield and, as with all phosphoramidite building blocks, has to be used in great excess over the support in standard automated synthesis. To extend the usefulness of this building block, we have directly coupled it to standard A, C, G and T long chain alkylamine-linked controlled pore glass supports to yield a solid phase-supported dimer. We then demonstrate that 13mers containing a 3'-terminal d(T[cis-syn]TN) group synthesized with this support at 0.2 micromol scale can be efficiently incorporated into longer oligonucleotides by both primer extension with 3'-->5'exonuclease-deficient Klenow fragment or T4 polymerase and dNTPs or by enzymatic ligation with T4 DNA ligase to another oligonucleotide opposite a complementary template. The site specificity and integrity of the cis-syn thymine dimer after both primer extension and ligation was confirmed by cis-syn dimer-specific cleavage with T4 denV endonuclease V. This general approach should be applicable to the synthesis of many types of site-specific nucleic acid modifications and would be of particular use for those for which the required building blocks are expensive or difficult to make.

Substrate and mispairing properties of 5-formyl-2'-deoxyuridine 5'-triphosphate assessed by in vitro DNA polymerase reactions

5-Formyluracil (fU) is one of the thymine lesions produced by reactive oxygen radicals in DNA and its constituents. In this work, 5-formyl-2'-deoxyuridine 5'-triphosphate (fdUTP) was chemically synthesized and extensively purified by HPLC. The electron withdrawing 5-formyl group facilitated ionization of fU. Thus, p K a of the base unit of fdUTP was 8.6, significantly lower than that of parent thymine (p K a = 10.0 as dTMP). fdUTP efficiently replaced dTTP during DNA replication catalyzed by Escherichia coli DNA polymerase I (Klenow fragment), T7 DNA polymerase (3'-5'exonuclease free) and Taq DNA polymerase. fU-specific cleavage of the replication products by piperidine revealed that when incorporated as T, incorporation of fU was virtually uniform, suggesting minor sequence context effects on the incorporation frequency of fdUTP. fdUTP also replaced dCTP, but with much lower efficiency than that for dTTP. The substitution efficiency for dCTP increased with increasing pH from 7.2 to 9.0. The parallel correlation between ionization of the base unit of fdUTP (p K a = 8.6) and the substitution efficiency for dCTP strongly suggests that the base-ionized form of fdUTP is involved in mispairing with template G. These data indicate that fU can be specifically introduced into DNA as unique lesions by in vitro DNA polymerase reactions. In addition, fU is potentially mutagenic since this lesion is much more prone to form mispairing with G than parent thymine.

Conformational and electronic properties of the two cis (5S,6R) and (5R,6S) diastereoisomers of 5,6-dihydroxy-5,6-dihydrothymidine: X-ray and theoretical studies

The structure of (+)-cis-(5S,6R)-5,6-dihydroxy-5,6-dihydrothymidine was obtained using X-ray crystallography [space group P2(1) with a = 10.130(3) angstroms, b = 6.434(9) angstroms, c = 11.02(5) angstroms, and beta = 112.646(2) angstroms]. The comparison of the two cis diastereoisomers of thymidine glycol (I, II) showed several structural and conformational differences. The solid state structures appear to be in agreement with the results of 1H NMR studies which were carried out in aqueous solution. Conformational and electronic properties of the ground state of the molecules I and II were obtained using ab initio LSD-DFT theory. Only slight differences between the crystal structure and the optimized geometry are observed for each of the two oxidized nucleosides. On the other hand, molecules I and II exhibit significant differences in their electronic properties. In particular, the dipole moment of (5S,6R)-thymidine glycol (I) is twice smaller than that of the (5R,6S) diastereoisomer (II). It is noteworthy that these differences in the electronic properties between the two compounds may be related to changes in the rotameric population around the C4'-C5' bond. The repartition of the electrostatic potential is different in the two compounds. These observations lead to a better understanding of the structural changes when the above lesions are included within a DNA molecule.

Molecular dynamics simulations of the effects of ring-saturated thymine lesions on DNA structure

The effect of thymine lesions produced by radiation or oxidative damage on DNA structure was studied by molecular dynamics simulations of native and damaged DNA. Thymine in position 7 of native dodecamer d(CGCGAATTCGCG)2 was replaced by one of the four thymine lesions 5-hydroxy-5,6-dihydrothymine, 6-hydroxy-5,6-dihydrothymine (thymine photohydrate), 5,6-dihydroxy-5,6-dihydro-thymine (thymine glycol), and 5,6-dihydrothymine. Simulations were performed with Assisted Model Building with Energy Refinement force field. Solvent was represented by a rectangular box of water with periodic boundary conditions applied. A constant temperature and constant volume protocol was used. The observed level of distortions of DNA structure depends on the specific nature of the lesion. The 5,6-dihydrothymine does not cause distinguishable perturbations to DNA. Other lesions produce a dramatic increase in the rise parameter between the lesion and the 5' adjacent adenine. These changes are accompanied by weakening of Watson-Crick hydrogen bonds in the A6-T19 base pair on the 5' side of the lesion. The lesioned bases also show negative values of inclination relative to the helical axis. No changes in the pattern of backbone torsional angles are observed with any of the lesions incorporated into DNA. The structural distortions in DNA correlate well with known biological effects of 5,6-dihydrothymine and thymine glycol on such processes as polymerase action or recognition by repair enzymes.

Energetic basis for structural preferences in 5/6-hydroxy-5,6-dihydropyrimidines: products of ionizing and ultraviolet radiation action on DNA bases

The structures of all diastereoisomers of 5/6-hydroxy-5,6-dihydropyrimidines have been optimized with ab initio quantum chemical calculations using a 6-31G basis set. The energies of the optimized structures were calculated at the MP2/6-31G* level. The hydroxyl group prefers an equatorial over an axial orientation at the C(5) position of pyrimidines by 3-4 kcal/mol. At the C(6) position, the axial orientation of hydroxyl is preferred by 3-4 kcal/mol. The factors responsible for the different preferences result from dipolar intramolecular interactions between the hydroxyl and C(4) = O(4) on the one hand, and the N(1)-H(1) on the other hand. As a consequence of these structural preferences, the pseudo axial positions at C(5) and C(6), which are perpendicular to the molecular plane, can be occupied by different substituents. These pseudo axial groups are expected to be a major source of distortions to DNA structure with more bulky groups having a greater effect. This may constitute a structural basis for interpretation of experimental results on the biological consequences of pyrimidine lesions. The conclusions drawn from the calculations correlate well with experimental observations on the biological activities of thymine lesions.

Ab initio theoretical study of the structures of thymine glycol and dihydrothymine

The structures of all diastereoisomers of 5,6-dihydroxy-5,6-dihydrothymine (thymine glycol) an 5,6-dihydrothymine, two important DNA lesions, have been optimized with ab initio quantum chemical methods at a 6-31 G level of calculations. The methyl group on C5 of thymine glycol shows a strong preference for a pseudo axial orientation. In contrast, in 5,6-dihydrothymine a pseudo equatorial methyl is preferred. Consequently, the thymine glycol lesion is much more bulky than 5,6-dihydrothymine. This observation may explain the different biological consequences observed for the two lesions.

A novel method for site specific introduction of single model oxidative DNA lesions into oligodeoxyribonucleotides

Calf thymus terminal deoxynucleotidyl transferase was used to incorporate several products of oxidative base damage onto the 3' end of oligodeoxyribonucleotides. Under the defined conditions described in this report, single residues of dihydrothymine, beta-ureidoisobutyric acid, thymine glycol, urea, 7-hydro-8-oxoadenine, 7-hydro-8-oxoguanine, 5-hydroxycytosine and 5-hydroxyuracil were incorporated into oligodeoxyribonucleotides of different lengths. The reaction is both efficient and cost effective. The 3' termini of the reaction products were suitable substrates for ligation by phage T4 DNA ligase, facilitating greatly the construction of oligodeoxyribonucleotides containing unique and site specific oxidative DNA lesions.

Influence of nucleic acid base aromaticity on substrate reactivity with enzymes acting on single-stranded DNA

Stacking between aromatic amino acids and nucleic acid bases may play an important role in the interaction of enzymes with nucleic acid substrates. In such circumstances, disruption of base aromaticity would be expected to decrease enzyme activity on the modified substrates. We have examined the requirement for DNA base aromaticity of five enzymes that act on single-stranded DNA, T4 polynucleotide kinase, nucleases P1 and S1, and snake venom and calf spleen phosphodiesterases, by comparing their kinetics of reaction with a series of dinucleoside monophosphates containing thymidine or a ring-saturated derivative. The modified substrates contained either cis-5R,6S-di-hydro-5,6-dihydroxythymidine (thymidine glycol) or a mixture of the 5R and 5S isomers of 5,6-dihydrothymidine. It was observed that for all the enzymes, except snake venom phosphodiesterase, the parent molecules were better substrates than the dihydrothymidine derivatives, while the thymidine glycol compounds were significantly poorer substrates. Snake venom phosphodiesterase acted on the unmodified and dihydrothymidine molecules at almost the same rate. These results imply that for all the remaining enzymes base aromaticity is a factor in enzyme-substrate interaction, but that additional factors must contribute to the poorer substrate capacity of the thymidine glycol compounds. The influence of the stereochemistry of the dihydrothymidine derivatives was also investigated. We observed that nuclease P1 and S1 hydrolysed the molecules containing 5R-dihydrothymidine approximately 50-times faster than those containing the S-isomer. The other enzymes displayed no measurable stereospecificity.

Characterization of gamma-radiation induced decomposition products of thymidine-containing dinucleoside monophosphates by nuclear magnetic resonance spectroscopy

To study the chemical and biochemical influence of loss of base aromaticity, dinucleoside monophosphates containing cis-5R,6S-thymidine glycol (Tg) and 5R and 5S 5,6-dihydrothymidine (Th) were prepared from d-ApT and d-TpA by KMnO4 oxidation and rhodium-catalysed hydrogenation, respectively. One and two dimensional 1H NMR techniques were used to characterize the solution conformation of each of the modified dinucleoside monophosphates for comparison with the unmodified compounds. Coupling constant data show that all sugar moieties adopt a predominantly 2'-endo conformation. Estimates of proton-proton distances from two-dimensional NOE experiments reveal that most of the glycosidic bonds prefer the anti conformation. Analysis of the C5'-C4' (gamma) torsion angle of the hydroxymethyl group using 3JH4'H5' and 3JH4'H5" data indicate that these modifications to thymine have little effect on the gamma conformer populations. Although, in general, additions at C5 and C6 of thymine in d-ApT and d-TpA profoundly distort the pyrimidine, they do not otherwise significantly alter the conformation of these compounds relative to the unsubstituted dinucleoside monophosphates. The one exception is the thymine glycol of d-TgpA, which appears to have a higher syn population than the parent compound.

In vivo evidence that UV-induced C-->T mutations at dipyrimidine sites could result from the replicative bypass of cis-syn cyclobutane dimers or their deamination products

The major mutations induced by UV light are C-->T transitions at dipyrimidines and arise from the incorporation of A opposite the C of dipyrimidine photoproducts. The incorporation of A has most often been explained by the known preference of a polymerase to do so opposite noninstructional DNA damage such as an abasic site (A rule). There are also mechanisms that suppose, however, that cis-syn dipyrimidine photodimers are instructional. In one such mechanism (tautomer bypass), the incorporation of A is directed by the tautomer of a C of a dimer that is equivalent in base-pairing properties to U [Person et al. (1974) Genetics 78, 1035-1049]. In another mechanism (deamination bypass), the incorporation of A is directed by a U of a dimer that results from the deamination of the C of a dimer [Taylor & O'Day (1990) Biochemistry 29, 1624-1632]. The viability of these mechanisms was tested by obtaining the mutation spectrum of a TU dimer in Escherichia coli by application of a standard method for site-directed mutagenesis. To this end, a 41-mer containing a site-specific TU dimer was constructed via ligation of a dimer-containing decamer that was produced by triplet-sensitized irradiation and used to prime DNA synthesis on a uracil-containing (+) strand of an M13 clone containing a double mismatch opposite the dimer. The reaction mixture was used to transfect a uracil glycosylase proficient, photoproduct repair deficient E. coli host, and all progeny phage weakly hybridizing to the parental (+) or (-) strands were sequenced. Under non-SOS conditions the TU dimer almost completely blocked replication, while under SOS conditions it directed the incorporation of two As with much higher specificity (96%) than would an abasic site. The implications of these results to the mechanism of the UV-induced TC-->TT mutation, and by extension to the CT-->TT, CC-->TC, CC-->CT, and the tandem CC-->TT mutations, are discussed.

Polymerase chain reaction amplification of single-stranded DNA containing a base analog, 2-chloradenine

By utilization of polymerase chain reaction techniques, single-stranded DNA of defined length and sequence containing a purine analog, 2-chloroadenine, in place of adenine was synthesized. This was accomplished by a combination of standard polymerase chain amplification reactions with Thermus aquaticus DNA polymerase in the presence of four normal deoxynucleoside triphosphates, M13 duplex DNA as template, and two primers to generate double-stranded DNA 118 bases in length. An asymmetric polymerase chain reaction, which produced an excess of single-stranded 98-base DNA, was then conducted with 2-chloro-2'-deoxy-adenosine 5'-triphosphate in place of dATP and with only one primer that annealed internal to the original two primers. Standard polymerase chain reaction techniques alone conducted in the presence of the analog as the fourth nucleotide did not produce duplex DNA that was modified within both strands. This asymmetric technique allows the incorporation of an altered nucleotide at specific sites into large quantities of single-stranded DNA without using chemical phosphoramidite synthesis procedures and circumvents the apparent inability of DNA polymerase to synthesize fully substituted double-stranded DNA during standard amplification reactions. The described method will permit the study of the effects of modified bases in template DNA on a variety of protein-DNA interactions and enzymes.

Deoxyribonucleotide analogs as inhibitors and substrates of DNA polymerases

Inhibitory and substrate properties of analogs of deoxyribonucleoside triphosphates toward DNA polymerases are reviewed. A general introduction is followed by a description of DNA polymerases and the reaction that they catalyze, and sites at which substrate analogs may inhibit them. Effects of modifications in the major family of compounds, nucleotide derivatives, at the base, sugar and triphosphate portions of the molecule, are summarized with respect to retention of substrate properties and generation of inhibitory properties. Structure-activity relationships and the basis of selectivity in the second family of compounds, deoxyribonucleotide mimics, are also presented. Conclusions are drawn regarding the structural basis of inhibitor selectivity and mechanism, relationship between in vitro and in vivo effects of inhibitors, and the promise of inhibitors as probes for study of active sites of DNA polymerases.