Structure of a G.T.A triplet in an intramolecular DNA triplex.

A 32-base DNA oligonucleotide has been studied by one- and two-dimensional 1H NMR spectroscopy and is shown to form a stable, pyr.pur.pyr, intramolecular triple helical structure, with a four C loop and a TATA loop connecting the Watson-Crick- and Hoogsteen-paired strands, respectively. This triplex contains five T.A.T base triplets, two C+.G.C base triplets, and an unusual G.T.A base triplet which disrupts the pyr.pur.pyr motif. The G.T.A triplet consists of a Watson-Crick T.A base pair, with the T situated in the "purine strand" and the A situated in the "pyrimidine strand" and a G situated in the Hoogsteen-base-paired "pyrimidine strand" hydrogen bonded to the T. The base-pairing structure of the G.T.A triplet has been investigated and has been found to involve a single hydrogen bond from the guanine amino group to the O4 carbonyl of the thymine, leaving the guanine imino proton free. The specific amino proton involved in the hydrogen bond is the H2(2) proton. This orients the guanine such that its sugar is near the thymine methyl group. The guanine sugar adopts an N-type (C3'-endo) sugar pucker in this triplet. The stability of the G.T.A triplet within pyr.pur.pyr triplexes is discussed.     

Dynamics of charge transfer along an oligonucleotide at finite temperature

The quantum-statistical approach was used to describe the charge transfer in nucleotide sequences. The results of numerical modeling for hole transfer in the GTTGGG sequence with background temperature noise are given. It was shown that, since guanine has an oxidation potential lower than thymine, the hole created at the G donor in this sequence passes through the thymine barrier into the guanine triplet (acceptor) at a time of approximately 10 ps at a temperature of 37 degrees C.     

Accurate guanine:cytosine discrimination in T4 DNA ligase-based single nucleotide polymorphism analysis using an oxanine-containing ligation fragment

T4 DNA ligase-based mismatch detection methods have been proposed as useful strategies for single nucleotide polymorphism (SNP) analyses. However, there is a critical problem for cytosine/thymine (C/T) SNP analyses: guanine:thymine (G:T) mismatch is not distinguished from guanine:cytosine (G:C). Here we employed chemically modified nucleobases, such as oxanine and hypoxanthine, at the end of a ligation fragment and analyzed their influence on the ligation efficiency between G:C and G:T. Successful ligation for G:C and no ligation for G:T were observed when oxanine was employed adjacent to guanine in the ligation junction. This ligation method using an oxanine-containing fragment has strong potentials for the accurate analysis of C/T SNPs.     

The Deoxyribonucleic Acids of Some Protozoa and a Mould

SYNOPSIS. Methods have been developed for the isolation of deoxyribonucleic acids (DNA) from Tetrahymena pyriformis, Polytomella papillata , and Aspergillus tamarii. The DNA from these organisms contained adenine (A), thymine (T), guanine (G) and cytosine (C), and the usual base-pairing relationship, i.e., A = T; G = C was found. The ratio A + T/ G + C was 2.42, 1.42, and 1.08 for the DNA of the three organisms respectively. 5-Methylcytosine was absent in all cases.     

Sequence specificity in triple-helix formation: experimental and theoretical studies of the effect of mismatches on triplex stability

The specificity of a homopyrimidine oligonucleotide binding to a homopurine-homopyrimidine sequence on double-stranded DNA was investigated by both molecular modeling and thermal dissociation experiments. The presence of a single mismatched triplet at the center of the triplex was shown to destabilize the triple helix, leading to a lower melting temperature and a less favorable energy of interaction. A terminal mismatch was less destabilizing than a central mismatch. The extent of destabilization was shown to be dependent on the nature of the mismatch. Both single base-pair substitution and deletion in the duplex DNA target were investigated. When a homopurine stretch was interrupted by one thymine, guanine was the least destabilizing base on the third strand. However, G in the third strand did not discriminate between a C.G and an A.T base pair. If the stretch of purines was interrupted by a cytosine, the presence of pyrimidines (C or T) in the third strand yielded a less destabilizing effect than purines. This study shows that oligonucleotides forming triple helices can discriminate between duplex DNA sequences that differ by one base pair. It provides a basis for the choice of antigene oligonucleotide sequences targeted to selected sequences on duplex DNA.     

Temperature effect on the luminescence of synthetized Yt base in PVA film

The mean phosphorescence lifetimes, fluorescence yields and phosphorescence-to-fluorescence quantum yields ratios of Y_t base in PVA films were measured in the temperature range of 100–250°K. The quantum yield of triplet state formation was found to be temperature independent at a wide range of lower temperatures. The radiative and nonradiative rate constants for triplet state were measured.     

Radiative decay engineering. 2. Effects of Silver Island films on fluorescence intensity, lifetimes, and resonance energy transfer

Metallic surfaces can have unusual effects on fluorophores such as increasing or decreasing the rates of radiative decay and the rates of resonance energy transfer (RET). In the present article we describe the effects of metallic silver island films on the emission spectra, lifetimes, and energy transfer for several fluorophores. The fluorophores are not covalently coupled to the silver islands so that there are a range of fluorophore-to-metal distances. We show that proximity of fluorophores to the silver islands results in increased fluorescence intensity, with the largest enhancement for the lowest-quantum-yield fluorophores. Importantly, the metal-induced increases in intensity are accompanied by decreased lifetimes and increased photostability. These effects demonstrate that the silver islands have increased the radiative decay rates of the fluorophore. For solvent-sensitive fluorophores the emission spectra shifted to shorted wavelengths in the presence of the silver islands, which is consistent with a decrease of the apparent lifetime for fluorophores near the metal islands. We also observed an increased intensity and blue spectral shift for the protein human glyoxalase, which displays a low quantum yield for its intrinsic tryptophan emission. In this case the blue shift is thought to be due to increased emission from a buried low-quantum-yield tryptophan residue. Increased intensities were also observed for the intrinsic emission of the nucleic acid bases adenine and thymine and for single-stranded 15-mers poly(T) and poly(C). And finally, we observed increased RET for donors and acceptors in solution and when bound to double-helical DNA. These results demonstrate that metallic particles can be used to modify the emission from intrinsic and extrinsic fluorophores in biochemical systems.     

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.     

Loop stereochemistry and dynamics in transfer RNA

The stereochemistry and the dynamics of two loops of yeast tRNA-asp, the thymine loop and the anticodon loop, are compared in the hope of a better understanding of the relationships between loop sequence and loop topology. Both loops are seven residues long and both present sharp turns after the second residue, U33 and psi 55, stabilized by hydrogen bonds between N3-H of the pyrimidine and the phosphates of C36 and A58 and stacking interactions of the pyrimidine ring with the phosphates of U35 and A57, respectively. In the thymine loop, the two purines following C56, A57 and A58, open up to leave space for the intercalation of the first invariant guanine residue of the D-loop, while the two pyrimidine bases, which follow A58, turn away from the stacking pattern of the thymine arm and stack instead with the last base pair of the dihydrouridine arm A15-U48. In the anticodon loop, however, the bases G34 to C38 form an helical stack in continuity with the anticodon stem on the 3'-end. At the same time C36 forms Watson-Crick hydrogen bonds with G34 of a twofold symmetrically related molecule. The anticodon-anticodon base pairing interactions between symmetrically-related molecules are stabilized by stacking with the modified base G37 on both sides of the triplet. Some comparisons are made with the structure of yeast tRNA-phe and some implications about the structure of mitochondrial tRNAs are discussed.     

Flanking sequence effects within the pyrimidine triple-helix motif characterized by affinity cleaving.

Nearest neighbor interactions affect the stabilities of triple-helical complexes. Within a pyrimidine triple-helical motif, the relative stabilities of natural base triplets T.AT, C + GC, and G.TA, as well as triplets, D3.TA and D3.CG, containing the nonnatural deoxyribonucleoside 1-(2-deoxy-beta-D-ribofuranosyl)-4-(3-benzamido)phenylimidazole (D3) were characterized by the affinity cleaving method in the context of different flanking triplets (T.AT, T.AT: T.AT, C + GC: C + GC, T.AT: G + GC, C + GC). The to be insensitive to substitutions in either the 3' or 5' directions, while the relative stabilities of triple helices containing C + GC triplets decreased as the number of adjacent C + GC triplets increased. Triple helices incorporating a G.TA interaction were most stable when this triplet was flanked by two T.AT triplets and were adversely affected when a C + GC triplet was placed in the adjacent 5' direction. Similarly, complexes containing D3.TA or D3.CG triplets were most stable when the triplet was flanked by two T.AT triplets but were destabilized when the adjacent 3' neighbor position was occupied with a C + GC triplet. This information regarding sequence composition effects in triple-helix formation establishes a set of guidelines for targeting sequences of double-helical DNA by the pyrimidine triple-helix motif.     

Dependence of substrate binding and catalysis on pH, ionic strength, and temperature for thymine DNA glycosylase: Insights into recognition and processing of G·T mispairs

Repair of G·T mismatches arising from deamination of 5-methylcytosine (m(5)C) involves excision of thymine and restoration of a G·C pair via base excision repair (BER). Thymine DNA glycosylase (TDG) is one of two mammalian enzymes that can specifically remove thymine from G·T mispairs. While TDG can excise other bases, it maintains stringent specificity for a CpG context, suggesting deaminated m(5)C is an important biological substrate. Recent studies reveal TDG is essential for embryogenesis; it helps to maintain an active chromatin complex and initiates BER to counter aberrant de novo CpG methylation, which may involve excision of actively deaminated m(5)C. The relatively weak G·T activity of TDG has been implicated in the hypermutability of CpG sites, which largely involves C→T transitions arising from m(5)C deamination. Thus, it is important to understand how TDG recognizes and process substrates, particularly G·T mispairs. Here, we extend our detailed studies of TDG by examining the dependence of substrate binding and catalysis on pH, ionic strength, and temperature. Catalytic activity is relatively constant for pH 5.5-9, but falls sharply for pH>9 due to severely weakened substrate binding, and, potentially, ionization of the target base. Substrate binding and catalysis diminish sharply with increasing ionic strength, particularly for G·T substrates, due partly to effects on nucleotide flipping. TDG aggregates rapidly and irreversibly at 37°C, but can be stabilized by specific and nonspecific DNA. The temperature dependence of catalysis reveals large and unexpected differences for G·U and G·T substrates, where G·T activity exhibits much steeper temperature dependence. The results suggest that reversible nucleotide flipping is much more rapid for G·T substrates, consistent with our previous findings that steric effects limit the active-site lifetime of thymine, which may account for the relatively weak G·T activity. Our findings provide important insight into catalysis by TDG, particularly for mutagenic G·T mispairs.     

Guanine tracts enhance sequence directed DNA bends.

Synthetic DNA fragments were constructed to determine the effect of G tracts, in conjunction with periodically spaced A tracts, on DNA bends. Relative length measurements showed that the G tracts spaced at the half helical turn enhanced the DNA bend. When the G tract was interrupted with a thymine or shortened to one or two guanines, the relative lengths decreased. If the G tract was replaced with either an A tract or a T tract, the bend was cancelled. Replacement with a C tract decreased the relative length to that of a thymine interruption suggesting that bend enhancement due to G tracts requires A tracts on the same strand.     

Novel mutational spectrum induced by N-methyl-N'-nitro-N-nitrosoguanidine in the coding region of the hypoxanthine (guanine) phosphoribosyltransferase gene in diploid human fibroblasts

The kinds and locations of mutations in the coding region of the hypoxanthine (guanine) phosphoribosyltransferase (hprt) gene of 75 independent mutants, derived from N-methyl-N'-nitro-N-nitrosoguanidine (MNNG)-treated normal human fibroblasts, were characterized by direct sequencing of mRNA-polymerase chain reaction (mRNA-PCR)-amplified cDNA. Treatment of human cells with low (6 or 8 microM) or high (10 or 12 microM) doses of MNNG resulted in 35-fold or 150-fold average increases in mutation frequency, respectively. A high frequency of mutants lacking a complete exon was observed in both groups. Further characterization of half of these mutants by DNA-PCR amplification of intron-exon boundaries showed that they contained base substitutions. The kinds of base substitutions differed distinctly between these two groups. In the low dose group, a broad mutational spectrum was observed: ten out of the 31 base substitutions were A.T to G.C transitions, six contained G.C to A.T transitions, and the other 15 exhibited transversions. In contrast, the majority (84%) of base substitutions among the high dose group were G.C to A.T transitions; the others (16%) were transversions. All of the 32 G.C to A.T transitions were located on the non-transcribed strand, assuming that the causative premutational lesion was O6-methylguanine. These results indicate preferential repair of lesions located on the transcribed strand. In addition, G.C to A.T and A.T to G.C transitions preferentially occurred at positions with guanine and thymine at the adjacent 5' position, respectively.     

Formation of DNA triple helices incorporating blocks of G.GC and T.AT triplets using short acridine-linked oligonucleotides.

We have used DNase I footprinting to assess triple helix formation at target sites containing the sequences A6G6.C6T6 and G6A6.T6C6. These sequences can be recognized by the acridine-linked oligopyrimidines Acr-T5C5 and Acr-C5T5 respectively at low pH, using well-characterised T.AT and C+.GC triplets. At pH 7.5 A6G6.C6T6 is specifically bound by Acr-G5T5, utilising G.GC and T.AT triplets in which the third strand runs antiparallel to the purine strand of the duplex. This interaction requires the presence of magnesium ions. No interaction was detected with Acr-T5G5, an oligonucleotide designed to form parallel G.GC and T.AT triplets. In contrast neither Acr-T5G5 nor Acr-G5T5 produced DNase I footprints with the target sequence G6A6.T6C6. These results suggest that, in an antiparallel R.RY triple helix, the T.AT triplet is weaker than the G.GC triplet. We find no evidence for the formation of structures containing parallel G.GC triplets.     

Conjugation-length dependence of the T1 lifetimes of carotenoids free in solution and incorporated into the LH2, LH1, RC, and RC-LH1 complexes: possible mechanisms of triplet-energy dissipation

In addition to the roles of antioxidant and spacer, carotenoids (Cars) in purple photosynthetic bacteria pursue two physiological functions, i.e., light harvesting and photoprotection. To reveal the mechanisms of the photoprotective function, i.e., quenching triplet bacteriochlorophyll to prevent the sensitized generation of singlet oxygen, the triplet absorption spectra were recorded for Cars, where the number of conjugated double bonds (n) is in the region of 9-13, to determine the dependence on n of the triplet lifetime. The Cars examined include those in (a) solution; (b) the reconstituted LH1 complexes; (c) the native LH2 complexes from Rba. sphaeroides G1C, Rba. sphaeroides 2.4.1, Rsp. molischianum, and Rps. acidophila 10050; (d) the RCs from Rba. sphaeroides G1C, Rba. sphaeroides 2.4.1, and Rsp. rubrum S1; and (e) the RC-LH1 complexes from Rba. sphaeroides G1C, Rba. sphaeroides 2.4.1, Rsp. molischianum, Rps. acidophila 10050, and Rsp. rubrum S1. The results lead us to propose the following mechanisms: (i) A substantial shift of the linear dependence to shorter lifetimes on going from solution to the LH2 complex was ascribed to the twisting of the Car conjugated chain. (ii) A substantial decrease in the slope of the linear dependence on going from the reconstituted LH1 to the LH1 component of the RC-LH1 complex was ascribed to the minor-component Car forming a leak channel of triplet energy. (iii) The loss of conjugation-length dependence on going from the isolated RC to the RC component of the RC-LH1 complex was ascribed to the presence of a triplet-energy reservoir consisting of bacteriochlorophylls in the RC component.     

Effect of strand orientation on the interaction of berenil with DNA triple helices

Using circular dichroism spectroscopy the ability of berenil, a minor groove binding drug, to induce triple helix formation was investigated with two oligonucleotides designed to form two intramolecular triplexes containing T*A:T and G*G:C triplets, which differ only by the orientation of their third strand: 5'-d(G4A4G4-[T4]-C4T4C4-[T4]-G4T4G4), and 5'-d(G4T4G4-[T4]-G4A4G4-[T4]-C4T4C4), where [T4] represents a stretch of four thymine residues. We demonstrate that when added to the duplex form of these oligonucleotides, berenil induces triplex structure formation only if the orientation of third strand is anti-parallel to the purine strand.     

Mutations induced by 5-formyl-2'-deoxyuridine in Escherichia coli include base substitutions that can arise from mispairs of 5-formyluracil with guanine, cytosine and thymine

5-Formyluracil (5-foU) is a major oxidation product of thymine formed in yields comparable to that of 8-oxoguanine in DNA by ionizing radiation. Whereas the mutagenic effects of 8-oxoguanine are well understood, the investigation of the biological implications of 5-foU has so far been limited. Here we demonstrate that 5-formyl-2'-deoxyuridine (5-fodUrd) supplied to the growth medium of Escherichia coli induces several base substitutions at different frequencies at position 461 in the lacZ gene in the following order: A.T-->G.C>G.C-->A.T>G.C-->T.A>A.T-->T.A>A.T-->C.G. No induction of G.C-->C.G transversions was observed. It is inferred that 5-fodUrd will be incorporated into the DNA during cell growth, forming mispairs with guanine, cytosine and thymine during replication. It, thus, appears that cell growth in the presence of 5-fodUrd may represent a good model for elucidating the cellular effects of 5-foU residues in DNA.     

Loop Stereochemistry and Dynamics in Transfer RNA

Abstract

The stereochemistry and the dynamics of two loops of yeast tRNA-asp, the thymine loop and the anticodon loop, are compared in the hope of a better understanding of the relationships between loop sequence and loop topology. Both loops are seven residues long and both present sharp turns after the second residue, U33 and ψ55, stabilized by hydrogen bonds between N3-H of the pyrimidine and the phosphates of C36 and A58 and stacking interactions of the pyrimidine ring with the phosphates of U35 and A57, respectively. In the thymine loop, the two purines following C56, A57 and A58, open up to leave space for the intercalation of the first invariant guanine residue of the D-loop, while the two pyrimidine bases, which follow A58, turn away from the stacking pattern of the thymine arm and stack instead with the last base pair of the dihydrouridine arm A15-U48. In the anticodon loop, however, the bases G34 to C38 form an helical stack in continuity with the anticodon stem on the 3′-end. At the same time C36 forms Watson-Crick hydrogen bonds with G34 of a twofold symmetrically related molecule. The anticodon-anticodon base pairing interactions between symmetrically-related molecules are stabilized by stacking with the modified base G37 on both sides of the triplet. Some comparisons are made with the structure of yeast tRNA-phe and some implications about the structure of mitochondrial tRNAs are discussed.     

Stoichiometry and affinity for thymine DNA glycosylase binding to specific and nonspecific DNA

Deamination of 5-methylcytosine to thymine creates mutagenic G · T mispairs, contributing to cancer and genetic disease. Thymine DNA glycosylase (TDG) removes thymine from these G · T lesions, and follow-on base excision repair yields a G · C pair. A previous crystal structure revealed TDG (catalytic domain) bound to abasic DNA product in a 2:1 complex, one subunit at the abasic site and the other bound to undamaged DNA. Biochemical studies showed TDG can bind abasic DNA with 1:1 or 2:1 stoichiometry, but the dissociation constants were unknown, as was the stoichiometry and affinity for binding substrates and undamaged DNA. We showed that 2:1 binding is dispensable for G · U activity, but its role in G · T repair was unknown. Using equilibrium binding anisotropy experiments, we show that a single TDG subunit binds very tightly to G · U mispairs and abasic (G · AP) sites, and somewhat less tightly G · T mispairs. Kinetics experiments show 1:1 binding provides full G · T activity. TDG binds undamaged CpG sites with remarkable affinity, modestly weaker than G · T mispairs, and exhibits substantial affinity for nonspecific DNA. While 2:1 binding is observed for large excess TDG concentrations, our findings indicate that a single TDG subunit is fully capable of locating and processing G · U or G · T lesions.     

Kinetics for exchange of imino protons in the d(C-G-C-G-A-A-T-T-C-G-C-G) double helix and in two similar helices that contain a G . T base pair, d(C-G-T-G-A-A-T-T-C-G-C-G), and an extra adenine, d(C-G-C-A-G-A-A-T-T-C-G-C-G)

The relaxation lifetimes of imino protons from individual base pairs were measured in (I) a perfect helix, d(C-G-C-G-A-A-T-T-C-G-C-G), (II) this helix with a G . C base pair replaced with a G . T base pair, d(C-G-T-G-A-A-T-T-C-G-C-G), and (III) the perfect helix with an extra adenine base in a mismatch, d(C-G-C-A-G-A-A-T-T-C-G-C-G). The lifetimes were measured by saturation recovery proton nuclear magnetic resonance experiments performed on the imino protons of these duplexes. The measured lifetimes of the imino protons were shown to correspond to chemical exchange lifetimes at higher temperatures and spin-lattice relaxation times at lower temperatures. Comparison of the lifetimes in these duplexes showed that the destabilizing effect of the G . T base pair in II affected the opening rate of only the nearest-neighbor base pairs. For helix III, the extra adenine affected the opening rates of all the base pairs in the helix and thus was a larger perturbation for opening of the base pairs than the G . T base pair. The temperature dependence of the exchange rates of the imino proton in the perfect helix gives values of 14-15 kcal/mol for activation energies of A . T imino protons. These relaxation rates were shown to correspond to exchange involving individual base pair opening in this helix, which means that one base-paired imino proton can exchange independent of the others. For the other two helices that contain perturbations, much larger activation energies for exchange of the imino protons were found, indicating that a cooperative transition involving exchange of at least several base pairs was the exchange mechanism of the imino protons. The effects of a perturbation in a helix on the exchange rates and the mechanisms for exchange of imino protons from oligonucleotide helices are discussed.