Hydroxylamine and methoxyamine mutagenesis: displacement of the tautomeric equilibrium of the promutagen N6-methoxyadenosine by complementary base pairing

The imino-amino tautomeric equilibrium of the promutagenic adenosine analogue N6-methoxy-2',3',5'-tri-O-methyladenosine [OMe6A(Me)3], in solvents of various polarities, has been studied with the aid of 1H and 13C NMR spectroscopy. The high energy barrier (free enthalpy delta G = 80 +/- 5 kJ X mol-1) between the two tautomeric species renders possible direct observation of the independent sets of all 1H and 13C signals from each of them. The equilibrium ranges from 10% imino in CCl4 to 90% in aqueous medium. Thermodynamic parameters, including energy barriers and lifetimes, were calculated from the temperature dependence of the equilibrium. Essentially similar results prevail for the promutagenic N6-hydroxy analogue. The conformations of the sugar moieties, and of the base about the glycosidic bond, for both tautomers are similar to those for adenosine. The conformation of the exocyclic N6-OCH3 group, which determines the ability of each species to form planar associates (hydrogen-bonded base pairs), has also been evaluated. Formation of autoassociates of OMe6A(Me)3 and of heteroassociates with the potentially complementary 2',3',5'-tri-O-methyluridine and -cytidine, in chloroform solution, was also investigated. The amino form base pairs with uridine and the imino form with cytidine. Formation of a complementary base pair by a given tautomeric species was accompanied by an increase of up to 10% in the population of this species and a concomitant decrease in population of the other species.(ABSTRACT TRUNCATED AT 250 WORDS)     

Acid-induced exchange of the imino proton in G.C pairs.

Acid-induced catalysis of imino proton exchange in G.C pairs of DNA duplexes is surprisingly fast, being nearly as fast as for the isolated nucleoside, despite base-pair dissociation constants in the range of 10(-5) at neutral or basic pH. It is also observed in terminal G.C pairs of duplexes and in base pairs of drug-DNA complexes. We have measured imino proton exchange in deoxyguanosine and in the duplex (ATATAGATCTATAT) as a function of pH. We show that acid-induced exchange can be assigned to proton transfer from N7-protonated guanosine to cytidine in the open state of the pair. This is faster than transfer from neutral guanosine (the process of intrinsic catalysis previously characterized at neutral ph) due to the lower imino proton pK of the protonated form, 7.2 instead of 9.4. Other interpretations are excluded by a study of exchange catalysis by formiate and cytidine as exchange catalysts. The cross-over pH between the regimes of pH-independent and acid-induced exchange rates is more basic in the case of base pairs than in the mononucleoside, suggestive of an increase by one to two decades in the dissociation constant of the base pair upon N7 protonation of G. Acid-induced catalysis is much weaker in A.T base pairs, as expected in view of the low pK for protonation of thymidine.     

Variation of nonexchangeable proton resonance chemical shifts as a probe of aberrant base pair formation in DNA

Variation of nonexchangeable proton resonance chemical shifts for deoxycytidine and deoxy-adenosine as a function of protonation and imino tautomer formation has been determined. Protonation induces downfield shifts of proton resonances whereas formation of the rare imino tautomer induces upfield shifts. Titration curves are constructed on the basis of spectrophotometrically determined pK values. Excellent fit is obtained between theoretical titration curves and experimental data, which indicates that chemical shifts of base protons may be used to quantitatively determine the relative concentrations of either rare imino tautomeric conformations or protonated base forms. These data may be utilized as an aid in the elucidation of the nature of hydrogen bonding between mismatched base pairs in DNA oligomers containing cytosine or adenine residues. These data, in conjunction with the oligonucleotide study of Patel et al. [Patel, D. J., Kozlowski, S.A., Ikuta, S., & Itakura, K. (1984) Biochemistry 23, 3218-3226], have been used to rigorously argue the existence of a "protonated" adenine residue in the A-C mismatch. This structure allows reconciliation of the NMR solution data with crystallographic data [Hunter, W.N., Brown, T., Anand, N.N., & Kennard, O. (1986) Nature (London) 320, 552-555], which support the protonated base pair.     

Processes of base-pair opening and proton exchange in Z-DNA

Using proton magnetic resonance, we have investigated imino and amino proton exchange in the Z form of the four oligomers d(Cbr8GCGCbr8G), d(CGm5CGCG), d(CG)6, and d(CG)12. In the latter two oligomers, all five exchangeable protons have been assigned. We find that proton acceptors such as NH3 or the basic form of Tris enhance imino proton exchange. The base-pair lifetime can then be obtained by extrapolation of the exchange time to infinite concentration of proton acceptor. For d(CG)6 and d(CG)12, the values are ca. 3.5 ms at 80 degrees C and ca. 130 ms at 35 degrees C. The latter value is about 65 times longer than in the same oligomers in the B form. The activation energy of base-pair opening, 80 kJ/mol, is the same in the Z and the B forms of d(CG)12. At 5 degrees C, the base-pair lifetime is about 3 s, much smaller than the time constant of the Z to B transition, to which it is therefore unrelated. The base-pair dissociation constant at 35 degrees C, 0.5 X 10(-6), is 5 times smaller than for the same oligomers in the B form. In the absence of added catalyst, at pH 7, the exchange time of the imino proton is 30 min at 5 degrees C. That of both cytidine amino protons, assigned by NOE, is about 50 min. The longest proton exchange time, ca. 330 min, is assigned unambiguously to the guanosine amino protons. Thus assigned and interpreted in terms of exchange chemistry rather than structural kinetics, the exchange times do not support earlier models of Z-DNA internal motions.     

The effect of tautomeric constant on the specificity of nucleotide incorporation during DNA replication: support for the rare tautomer hypothesis of substitution mutagenesis

The nucleoside analogue dP (6-(2-deoxy-beta-D-ribofuranosyl)-3,4-dihydro-6H,8H-pyrimido[4,5-c][1,2]oxazin-2-one) displays ambivalent hydrogen bonding characteristics whereby the imino tautomer of P can base-pair with adenine and its amino tautomer can base-pair with guanine. Fixed imino and amino tautomers of 6-methyl-3,4-dihydro-6H,8H-pyrimido[4,5-c][1,2]oxazin-2-one (N-methyl P) have been synthesised and their structures obtained by X-ray crystallography. The tautomeric constant of N-methyl P has been calculated from pK(a) values of the fixed tautomers and the kinetic parameters for the incorporation of its 5'-triphosphate (dPTP) by exonuclease-free Klenow fragment of DNA polymerase I have been determined. A strong correlation between the tautomeric constant and the incorporation specificity of dPTP is found. These results lend support to the proposal that the minor tautomeric forms of the natural bases may play an important role in substitution mutagenesis during DNA replication. Furthermore, they imply that DNA polymerases impose specific steric requirements on the base-pair during nucleotide incorporation.     

An explanation of the induction of mutations by 2-aminopurine from an ab initio molecular orbital study

The molecular mechanism of induction of mutations by 2-aminopurine (AP) was studied by an ab initio molecular orbital method. Cytosine (C) is converted to its disfavored imino tautomer more easily than AP, judging from the calculated total energies of the bases and the base analogue. This suggests that a stable AP:C base mispair via two hydrogen bonds can be formed with the imino tautomer of C. These results stress the importance of the imino form of C in AP-induced mutagenesis and support the 'trigger mechanism', in which formation of one hydrogen bond between AP and C is considered to stimulate the tautomeric shift of AP or C. The calculated relative stabilities of various base pairs and mispairs were in good agreement with experimental findings.     

Helix opening in deoxyribonucleic acid from a proton nuclear magnetic resonance study of imino and amino protons in d(CG)3.

All exchangeable protons in a short DNA helix, d(CG)3 sodium salt, have been studied by proton nuclear magnetic resonance. The cytidine and guanosine amino protons have been assigned for the first time. As a function of temperature the cytidine amino protons and the imino protons behave very similarly, their relaxation is dominated by exchange with solvent above 30 degrees C. The guanosine amino protons, however, show that helix opening can only be described by a multistate model. The most rapid process observed is probably a twist about the helix axis which lengthens or breaks the guanosine amino hydrogen bond and allows rotation of the amino group. The second fastest process is a scissor opening into the major groove which gives rise to solvent exchange with the imino and cytidine amino protons. The slowest process observed is the complete base pair opening in which the guanosine amino protons also exchange with solvent. For the ammonium salt of the oligonucleotide, a specific ammonium ion complex is observed which at low temperature may catalyze exchange of the guanosine amino protons with the protons of the ammonium ion, but retards exchange with solvent. The complex appears to be specific for the sequence d(CpG).     

Evidence for tautomerism in nucleic acid base pairs. 1H NMR study of 15N labeled tRNA.

The imino proton resonances of 15N labeled tRNA appear as asymmetric doublet signals, the asymmetry being dependent on the applied magnetic field strength. Assuming a tautomerism of the type N-H...N not equal to N...H-N in the base pairs the line shapes can be simulated. The most important parameters fitted in the simulation are the rate constants of the proton transfer and the mole fractions of either tautomeric state. The rate constants are of the order of 100s-1 and the mole fractions of the non dominant tautomer about 0.1 depending on the temperature and on the nature of the base pairing. The observations are attributed to a double proton transfer in the base pairs. The unexpectedly slow rates of the double proton transfer process may be connected with a concomitant conformational change of the duplex structure.     

NMR structural studies of intramolecular (Y+)n.(R+)n(Y-)nDNA triplexes in solution: imino and amino proton and nitrogen markers of G.TA base triple formation.

We reported previously on NMR studies of (Y+)n.(R+)n(Y-)n DNA triple helices containing one oligopurine strand (R)n and two oligopyrimidine strands (Y)n stabilized by T.AT and C+.GC base triples [de los Santos, C., Rosen, M., & Patel, D. J. (1989) Biochemistry 28, 7282-7289]. Recently, it has been established that guanosine can recognize a thymidine.adenosine base pair to form a G.TA triple in an otherwise (Y+)n.(R+)n(Y-)n triple-helix motif. [Griffin, L. C., & Dervan, P. B. (1989) Science 245, 967-971]. The present study extends the NMR research to the characterization of structural features of a 31-mer deoxyoligonucleotide that folds intramolecularly into a 7-mer (Y+)n.(R+)n(Y-)n triplex with the strands linked through two T5 loops and that contains a central G.TA triple flanked by T.AT triples. The G.TA triplex exhibits an unusually well resolved and narrow imino and amino exchangeable proton and nonexchangeable proton spectrum in H2O solution, pH 4.85, at 5 degrees C. We have assigned the imino protons of thymidine and amino protons of adenosine involved in Watson-Crick and Hoogsteen pairing in T.AT triples, as well as the guanosine imino and cytidine amino protons involved in Watson-Crick pairing and the protonated cytidine imino and amino protons involved in Hoogsteen pairing in C+.GC triples in the NOESY spectrum of the G.TA triplex. The NMR data are consistent with the proposed pairing alignment for the G.TA triple where the guanosine in an anti orientation pairs through a single hydrogen bond from one of its 2-amino protons to the 4-carbonyl group of thymidine in the Watson-Crick TA pair.(ABSTRACT TRUNCATED AT 250 WORDS)     

Proton nuclear magnetic resonance investigation of the conformation and dynamics in the synthetic deoxyribonucleic acid decamers d(ATATCGATAT) and d(ATATGCATAT)

A variety of one-dimensional proton NMR methods have been used to investigate the properties of two synthetic DNA decamers, d(ATATCGATAT) and d(ATATGCATAT). These results, in conjunction with the results of two-dimensional NMR experiments, permit complete assignment of the base proton resonances. Low-field resonances were assigned by sequential "melting" of the A . T base pairs and by comparison of the spectra of the two decamers. Below 20 degree C spin-lattice relaxation is dominated by through-space dipolar interactions. A substantial isotope effect on the G imino proton relaxation is observed in 75% D2O, confirming the importance of the exchangeable amino protons in the relaxation process. A somewhat smaller isotope effect is observed on the T imino proton relaxation. At elevated temperatures spin-lattice relaxation of the imino protons is due to proton exchange with solvent. Apparent activation energies for exchange vary from 36 kcal/base pair for base pairs (3,8) to 64 kcal/mol for the most interior base pairs (5,6), indicating that disruption of part, or all, of the double helix contributes significantly to the exchange of the imino protons in these decamers. By contrast, single base pair opening events are the major low-temperature pathways for exchange from A X T and G X C base pairs in the more stable higher molecular weight DNA examined in other studies. The temperature dependence of the chemical shifts and line widths of certain aromatic resonances indicates that the interconversion between the helix and coil states is not in fast exchange below the melting temperature, Tm. Within experimental error, no differential melting of base pairs was found in either molecule, and both exhibited melting points Tm = 50-52 degrees C. Spin-spin and spin-lattice relaxation rates of the nonexchangeable protons (TH6, AH8, and AH2) are consistent with values calculated by using an isotropic rotor model with a rotational correlation time of 6 ns and interproton distances appropriate for B-family DNA. The faster decay of AH8 compared with GH8 is attributed to an interaction between the thymine methyl protons and the AH8 protons in adjacent adenines (5'ApT3'). The base protons (AH8, GH8, and TH6) appear to be located close (1.9-2.3 A) to sugar H2',2" protons.(ABSTRACT TRUNCATED AT 400 WORDS)     

1H-NMR studies of the interaction between a self-complementary deoxyoligonucleotide duplex and indolo[2,3-b]quinoxaline derivatives active against herpes virus

1H NMR has been used to study the interactions of ellipticine and the ellipticine analogues 2-3-dimethyl-6-(2-dimethylaminoethyl)6H-indolo-[2,3-b]quinoxaline and 6-(2-dimethylaminoethyl)6H-indolo-[2,3-b]quinoxaline with the self-complementary decadeoxyribonucleotide d(CGCGATCGCG)2. The Watson-Crick H-bonded imino proton resonances were studied. The drugs were shown to bind to the duplex by intercalation involving slow exchange kinetics for the imino proton resonances on the NMR time scale (500 MHz). Ellipticine and the 2,3-dimethyl analogue were found not to show strong base preferences, while the other analogue was found to have a preferred primary binding site between the A.T base pairs with a probable minor secondary binding site between the A.T and adjacent G.C base pairs. The new drug-shifted imino proton resonances were assigned through saturation transfer experiments. The base-specific interactions were accompanied by drug-induced non-uniform broadening of the resonances (due to intermediate chemical exchange kinetics), in the spectral region of the non-exchangeable aromatic and sugar H1' proton resonances of the oligonucleotide at 25 degrees C.     

NMR studies on oligodeoxyribonucleotides containing the dam methylation site GATC. Comparison between d(GGATCC) and d(GGm6ATCC)

The conformation of two hexanucleotides, d(GGATCC) and d(GGm6ATCC), has been studied by proton nuclear magnetic resonance. Nuclear Overhauser effect (NOE) measurements on d(GGATCC) are in agreement with a normal B form right-handed helical structure. The single- and double-strand resonances are in fast exchange on a proton NMR time scale. The exchange is observed to be slow for d(GGm6ATCC); up to the Tm, separate resonances are observed for each state, though above the Tm exchange becomes more rapid. The preferred orientation of the adenosine methylamino group (methyl cis to N1) hinders base-pair formation. At 0 degree C irradiation of the m6A-T imino proton gives an NOE to AH2, showing that base pairing is Watson-Crick. Intra- and interresidue NOEs show that the helix is right handed and in the B form. Comparing results on the two oligomers demonstrates that adenosine methylation induces little or no change in the conformation of the helix but reduces the Tm from 45 to 32 degrees C. All of the amino proton resonances, as well as the imino resonances, have been assigned. From NOE experiments on the unmethylated oligomer we have located the Watson-Crick and non-Watson-Crick adenosine amino protons. At 0 degree C these resonances show broadening due to rotation of the amino group, and their rotation is slightly slower than for the adjacent guanosine amino group, though both these amino groups have lifetimes of less than 10 ms at 0 degree C. The imino protons show normal behavior, disappearing from the spectra ca. 20 degrees C below the Tm.(ABSTRACT TRUNCATED AT 250 WORDS)     

Deoxyguanosine-deoxyadenosine pairing in the d(C-G-A-G-A-A-T-T-C-G-C-G) duplex: conformation and dynamics at and adjacent to the dG X dA mismatch site

Nuclear magnetic resonance (NMR) has been used to monitor the conformation and dynamics of the d-(C1-G2-A3-G4-A5-A6-T6-T5-C4-G3-C2-G1) self-complementary dodecanucleotide (henceforth called 12-mer GA) that contains a dG X dA purine-purine mismatch at position 3 in the sequence. These results are compared with the corresponding d(C-G-C-G-A-A-T-T-C-G-C-G) dodecamer duplex (henceforth called 12-mer) containing standard Watson-Crick base pairs at position 3 [Patel, D.J., Kozlowski, S.A., Marky, L.A., Broka, C., Rice, J.A., Itakura, K., & Breslauer, K.J. (1982) Biochemistry 21, 428-436]. The dG X dA interaction at position 3 was monitored at the guanosine exchangeable H-1 and nonexchangeable H-8 protons and the nonexchangeable adenosine H-2 proton. We demonstrate base-pair formation between anti orientations of the guanosine and adenosine rings on the basis of nuclear Overhauser effects (NOE) observed between the H-2 proton of adenosine 3 and the imino protons of guanosine 3 (intra base pair) and guanosines 2 and 4 (inter base pair). The dG(anti) X dA(anti) pairing should result in hydrogen-bond formation between the guanosine imino H-1 and carbonyl O-6 groups and the adenosine N-1 and NH2-6 groups, respectively. The base pairing on either side of the dG X dA pair remains intact at low temperature, but these dG X dC pairs at positions 2 and 4 are kinetically destabilized in the 12-mer GA compared to the 12-mer duplex. We have estimated the hydrogen exchange kinetics at positions 4-6 from saturation-recovery measurements on the imino protons of the 12-mer GA duplex between 5 and 40 degrees C. The measured activation energies for imino proton exchange in the 12-mer GA are larger by a factor of approximately 2 compared to the corresponding values in the 12-mer duplex. This implies that hydrogen exchange in the 12-mer GA duplex results from a cooperative transition involving exchange of several base pairs as was previously reported for the 12-mer containing a G X T wobble pair at position 3 [Pardi, A., Morden, K.M., Patel, D.J., & Tinoco, I., Jr. (1982) Biochemistry 21, 6567-6574]. We have assigned the nonexchangeable base protons by intra and inter base pair NOE experiments and monitored these assigned markers through the 12-mer GA duplex to strand transition.(ABSTRACT TRUNCATED AT 400 WORDS)     

A theoretical study of the cis-syn pyrimidine dimers in the gas phase and water cluster and a tautomer-bypass mechanism for the origin of UV-induced mutations

A quantum mechanical study of all cis-syn cyclobutane pyrimidine photodimers including the normal and rare tautomeric forms of bases has been performed using the ab initio method at HF/6-31G(d.p), MP2(fc)//HF/6-31G(d,p) and MP2(fc)/6-31G(d,p) levels. A puckering angle of the cyclobutyl ring and twist angle of pyrimidine rings with respect to each other is well described by these calculations. It is predicted that in the gas phase all photodimers containing the rare imino form of cytosine are more stable than those containing its normal form. The Monte Carlo simulations show that the dimer containing the imino form of cytosine is more stabilized by water cluster than that containing its amino forms. The possible biological significance stems from the fact that the cytosine in the dimer directs the incorporation of adenine in the complementary strand during replicative bypass. Data obtained point to the cytosine tautomerism as a possible mechanism for the origin of UV-induced mutation.     

Proton exchange and internal motions in two chromomycin dimer-DNA oligomer complexes.

Previous structural studies on the complexes of the chromomycin (CHR) dimer with duplexes of d(A1-A2-G3-G4-C5-C6-T7-T8) and of d(A1-G2-G3-A4-T5-C6-C7-T8) in solution [one Mg(II) and two drugs per duplex] are extended to hydrogen exchange measurements. Exchange of the OH8 proton of chromomycin, measured by real time proton-deuterium exchange, is very slow and requires dissociation of the complex, whose lifetime is thus determined. The lifetimes and apparent dissociation constants of base pairs are deduced from the catalysis of imino proton exchange by ammonia. The four central base pairs, which interact with the CHR chromophores in the minor groove (Gao & Patel, 1990), may open within the complex, but the opening rate is less than in the free duplex by one to two orders of magnitude. The activation energy for base-pair opening and the differences between the lifetimes of adjacent pairs suggest that single base-pair opening is the predominant imino proton exchange pathway in all cases. In the symmetrical complex of chromomycin with the first duplex, the lifetimes of the central base pairs (G3.C6 and G4.C5) are in the same range (52 and 29 ms, respectively, at 38 degrees C). In the asymmetrical complex formed with the second duplex, the base-pair lifetimes in the G2-G3-A4-T5 segment that interacts with the chromophore moiety are strongly increased. That of G3.C6 is particularly long. Above 50 degrees C, exchange of the G3 imino proton is opening limited.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

A two-dimensional 1H-NMR study of the dam methylase site: comparison between the hemimethylated GATC sequence, its unmethylated analogue and a hemimethylated CATG sequence. The sequence dependence of methylation upon base-pair lifetimes

We report two-dimensional NOE (NOESY) spectra on the sequence d(GCGATCATGG).d(CCATGATCGC) which contains the unmethylated dam site. As expected the DNA adopts a B-form conformation but appears to be distorted at the TG step of the second strand. This distorsion, probably bending, is not seen on the opposite strand. When the first strand is methylated on adenine in the GATC or CATG sequence the NOESY spectra indicate little or no change in the conformation. However the single strand-duplex exchange is slowed down to the slow-exchange region on a proton NMR time scale. We have assigned the exchangeable imino and cytidine amino resonances of the three duplexes. From the imino linewidths as a function of temperature, we observe that the unmethylated and the hemimethylated Gm6ATC duplexes melt normally from the ends. However, this is not so for the hemimethylated Cm6ATG duplex which, apart from the terminal base pairs, melts cooperatively and at higher temperature. In spectra recorded in H2O a second duplex is observed, for the Gm6ATC sequence, which we have not been able to identify. It is however unlikely to be a hairpin structure. Ultraviolet-melting curves also indicate the presence of two transitions for this duplex. The effect of methylation upon base-pair lifetimes has been studied by comparing the above three duplexes. Little effect is observed upon methylation in the GATC sequence but a drastic increase in the lifetimes of all base pairs is observed upon methylation in the CATG sequence.     

UV spectra of adenine methyl and glycosyl derivatives and their transformation induced by amino acid carboxylic groups

UV absorption spectra of adenine, adenosine and their methyl derivatives were studied in dimethylsuloxide (DMSO). Considerable changes in UV spectra of adenine under methylation at the 1 and 3 positions, and adenosine under methylation at the 1 position attested the essential structural reconstruction of adenine purine ring. Ade and m6Ade were shown to form complexes with deprotonated carboxylic group of amino acids (carboxylate-ion) through two H-bonds involving amino group and N7H imino group, tautomeric transition N9H-->N7H being initiated namely by interaction with carboxylate-ion. Considerable changes in UV spectra of m1Ade, m1A, and m3Ade under interaction with neutral carboxylic group of amino acids were interpreted as a result of proton transfer from amino acid to the base.     

Dynamics of uracil and 5-fluorouracil in DNA

The prodrug 5-fluorouracil (5-FU), after activation into 5-F-dUMP, is an extensively used anticancer agent that inhibits thymidylate synthase and leads to increases in dUTP and 5-F-dUTP levels in cells. One mechanism for 5-FU action involves DNA polymerase mediated incorporation of dUTP and 5-F-dUTP into genomic DNA leading to U/A, 5-FU/A, or 5-FU/G base pairs. These uracil-containing lesions are recognized and excised by several human uracil excision repair glycosylases (hUNG2, hSMUG2, and hTDG) leading to toxic abasic sites in DNA that may precipitate cell death. Each of these enzymes uses an extrahelical base recognition mechanism, and previous studies with UNG have shown that extrahelical recognition is facilitated by destabilized base pairs possessing kinetically enhanced base pair opening rates. Thus, the dynamic properties of base pairs containing 5-FU and U are an important unknown in understanding the role of these enzymes in damage recognition and prodrug activation. The pH dependence of the (19)F NMR chemical shift of 5-FU imbedded in a model trinucleotide was used to obtain a pK(a) = 8.1 for its imino proton (10 °C). This is about 1.5 units lower than the imino protons of uracil or thymine and indicates that at neutral pH 5-FU exists significantly as an ionized tautomer that can mispair with guanine during DNA replication. NMR imino proton exchange measurements show that U/A and 5-FU/A base pairs open with rate constants (k(op)) that are 6- and 13-fold faster than a T/A base pair in the same sequence context. In contrast, these same base pairs have apparent opening equilibrium constants (αK(op)) that differ by less than a factor of 2, indicating that the closing rates (k(cl)) are enhanced by nearly equal amounts as k(op). These dynamic measurements are consistent with the previously proposed kinetic trapping model for extrahelical recognition by UNG. In this model, the enhanced intrinsic opening rates of destabilized base pairs allow the bound glycosylase to sample dynamic extrahelical excursions of thymidine and uracil bases as the first step in recognition.     

A Theoretical Study of the cis-syn Pyrimidine Dimers in the Gas Phase and Water Cluster and a Tautomer-Bypass Mechanism for the Origin of UV-induced Mutations

Abstract

A quantum mechanical study of all cis-syn cyclobutane pyrimidine photodimers including the normal and rare tautomeric forms of bases has been performed using the ab initio method at HF/6–31G(d,p), MP2(fc)//HF/6–31G(d,p) and MP2(fc)/6–31G(d,p) levels. A puckering angle of the cyclobutyl ring and twist angle of pyrimidine rings with respect to each other is well described by these calculations. It is predicted that in the gas phase all photodimers containing the rare imino form of cytosine are more stable than those containing its normal form. The Monte Carlo simulations show that the dimer containing the imino form of cytosine is more stabilized by water cluster than that containing its amino forms. The possible biological significance stems from the fact that the cytosine in the dimer directs the incorporation of adenine in the complementary strand during replicative bypass. Data obtained point to the cytosine tautomerism as a possible mechanism for the origin of UV-induced mutation.