Ultraviolet irradiation of nucleic acids: formation, purification, and solution conformational analyses of oligothymidylates containing cis-syn photodimers

Macrocyclic Zinc(II) Complexes for Selective Recognition of Nucleobases in Single- and Double-Stranded Polynucleotides

The model study of zinc enzyme by Zn2+–cyclen complexes (cyclen = 1, 4, 7, 10-tetraazacyclododecane) disclosed the intrinsic properties of zinc(II) as having strong anion affinities and yet the resulting Zn2+–anion bonds have a labile nature. The basic understanding has evolved into novel selective nucleobase recognition by the Zn2+–cyclen complexes. The Zn2+–aromatic pendant cyclen complexes selectively and effectively bind to thymine T (or uracil U) in single- and double-stranded DNA (or RNA). The Zn2+ complexes work like molecular zippers to break A–T pairs in double-stranded DNA, as proven by various physicochemical and DNA footprinting measurements. Moreover, these Zn2+–complexes affect relevant biochemical and ultimately biological properties such as inhibition of a transcriptional factor and antimicrobial activities.

DNA binding mode of the Fab fragment of a monoclonal antibody specific for cyclobutane pyrimidine dimer

Monoclonal antibodies specific for the cyclobutane pyrimidine dimer (CPD) are widely used for detection and quantification of DNA photolesions. However, the mechanisms of antigen binding by anti-CPD antibodies are little understood. Here we report NMR analyses of antigen recognition by TDM-2, which is a mouse monoclonal antibody specific for the cis - syn -cyclobutane thymine dimer (T[ c, s ]T). (31)P NMR and surface plasmon resonance data indicated that the epitope recognized by TDM-2 comprises hexadeoxynucleotides centered on the CPD. Chemical shift perturbations observed for TDM-2 Fab upon binding to d(T[ c, s ]T) and d(TAT[ c, s ]TAT) were examined in order to identify the binding sites for these antigen analogs. It was revealed that d(T[ c, s ]T) binds to the central part of the antibody-combining site, while the CPD-flanking nucleotides bind to the positively charged area of the V(H)domain via electrostatic interactions. By applying a novel NMR method utilizing a pair of spin-labeled DNA analogs, the orientation of DNA with respect to the antigen-binding site was determined: CPD-containing oligonucleotides bind to TDM-2 in a crooked form, draping the 3'-side of the nucleotides onto the H1 and H3 segments, with the 5'-side on the H2 and L3 segments. These data provide valuable information for antibody engineering of TDM-2.

An NMR and conformational investigation of the trans-syn cyclobutane photodimers of dUpdT

Both trans-syn cyclobutane-type photodimers of 2'-deoxyuridylyl (3'-5') thymidine (dUpdT) were formed by deamination of the corresponding trans-syn cyclobutane photodimers of 2'-deoxycytidylyl (3'-5') thymidine (dCpdT) and were examined by 1H-, 13C-, and 31P-nmr spectroscopy. One- and two-dimensional nmr experiments provided a nearly complete assignment of the 1H, 13C, and 31P resonances. Scalar and nuclear Overhauser effect contacts were used to determine the conformation of the deoxyribose rings, exocyclic bonds, cyclobutane rings, and glycosidic linkages. Isomer I (S-type class; CB-; SYN-ANTI) and isomer II (N-type class; CB+; ANTI-SYN) exhibit markedly different conformational features. 31P chemical shifts show that the relative flexibility is dUpdT > isomer II > isomer I. The conformations of these species are very similar to those of other previously examined trans-syn photodimers. Among bipyrimidine photodimers of a given diastereomeric form (i.e., trans-syn I or II), the nmr-derived conformational parameters are nearly invariant, regardless of base substitution pattern. This contrasts with the substituent-dependent variation of cyclobutane ring conformation observed by Kim et al. (Biopolymers, 1993, Vol. 33, pp. 713-721) for an analogous series of cis-syn photodimers. Steric crowding of cyclobutane ring substituents is offered as an explanation for the difference in substituent effects between the families of cis-syn and trans-syn photodimers.

Conformational studies of dithymidine boranomonophosphate diastereoisomers

The boranophosphate ester nucleotides are a new class of nucleic acid analogues that are isoelectronic and isostructural to normal phosphodiester nucleic acids and that maintain the anionic charge of the nucleic acid backbone. The two P-diastereoisomers of dithymidine boranomonophosphates were separated using reverse phase HPLC; the faster and slower eluting isomers are designated as d(TpBT)-1 and d(TpBT)-2, respectively. Conformations of the isomers were studied using-circular dichroism (CD) and NMR, and compared to the analogous phosphate diester, d(TpT). This comparison allowed the effects of the borane group and chirality of the boranophosphate linkage on sugar and base conformations to be assessed. The CD spectra of the diastereoisomers are consistent with both having a B-type conformation. Analysis of the 1H-1H and 1H-31P coupling constants showed that these conformations are similar to those of the unmodified parent dimer; specifically, the 2'-deoxyribose rings prefer the S (C2'-endo) conformation, and the C4'-C5' and C5'-O5' rotamers are primarily in the gamma + and beta + conformations, respectively. Conformational differences between the diastereoisomers and between the modified and unmodified dimers are manifested by differences in the preferences of the 3'-residues to adopt S sugar pucker and beta + conformations. There is reduced preference for the S sugar pucker of the 3'-residue in d(TpBT)-1 relative to d(TpBT)-2, which is similar to d(TpT). There is less preference for the beta + conformation of the 3'-residue in d(TpBT)-2 relative to d(TpBT)-1 and d(TpT). Based on the CD results, the temperature dependences of the thymidine H6 chemical shifts, and the derived sugar ring and backbone conformational parameters, we conclude that the borane group exerts a minimal influence on the sugar conformations and base stacking interactions. Preliminary assignment of the absolute configuration of the pair of SP and RP diastereoisomers to d(TpBT)-1 and d(TpBT)-2, respectively, is made on the basis of enzyme selectivity and NOE difference experiments.

Contrasting structural impacts induced by cis-syn cyclobutane dimer and (6-4) adduct in DNA duplex decamers: implication in mutagenesis and repair activity

The relative biological importance of cis--syn cyclobutane dimer and pyrimidine(6-4)pyrimidone photoadduct ([6-4] photoadduct) appears to be dependent on the biological species, dipyrimidine sites and local conformational variation induced at the damaged sites. The single-strained deoxynucleotide 10-mers containing the site-specific (6-4) adduct or cis--syn cyclobutane dimer of thymidylyl(3'-->5')-thymidine were generated by direct photolysis of d(CGCATTACGC) with UVC (220-260 nm) irradiation or UVB (260-320 nm) photosensitization. Three-dimensional structures of the duplex cis--syn and (6-4) decamers of d(CGCATTACGC)xd(GCGTAATGCG) were determined by NMR spectroscopy and the relaxation matrix refinement method. The NMR data and structural calculations establish that Watson-Crick base pairing is still intact at the cis--syn dimer site while the hydrogen bonding is absent at the 3'-side of the (6-4) lesion where the T-->C transition mutation is predominantly targeted. Overall conformation of the duplex cis--syn decamer was B-DNA and produced a 9 degree bending in the DNA helix, but a distinctive base orientation of the (6-4) lesion provided a structural basis leading to 44 degree helical bending. The observed local structure and conformational rigidity at the (6-4) adduct of the thymidylyl(3'-5')-thymidine (T-T [6-4]) lesion site suggest the potential absence of hydrogen bonding at the 3' sides of the (6-4) lesion with a substituted nucleotide during replication under SOS conditions. Contrasting structural distortions induced ny the T-T (6-4) adduct with respect to the T-T cis--syn cyclobutane pyrimidine photodimer may explain the large differences in mutation spectrum and repair activities between them.

Oligonucleotide model with non-identical complementary strands for chromatographic studies of structure-dependent photosusceptibility

In a previous work, we used a quantitative chromatographic analysis of two self-complementary oligonucleotides to correlate the conformational differences between the oligonucleotide duplexes and photochemical susceptibilities of constituent oligomers. In this work we describe a new double-stranded oligonucleotide model with non-identical complementary strands. To separately analyze photoproducts in two strands, one of them is used in a partially protected form (the hydrophobic 5'-dimethoxytrityl group uncleaved). Using a reversed-phase column, the oligomers and products of their UV photomodification are separated into two groups of peaks. This facilitates the quantitation of photoproducts in each of the complementary strands. Three 15-mer oligonucleotides, 5'-TTTTTAT-TAAATATA-3' (F5), 5'-AAAAATAATTTATAT-3' (F6) and 5'-TATATTTAATAAAAA-3' (F7) form the parallel-stranded (ps) F5.F6 and the ordinary antiparallel-stranded (aps) F5.F7 duplexes. For these particular sequences, the rate of cyclobutane thymine dimer formation in the ps DNA has been estimated as ca. 1.5-2 times that in the ordinary aps DNA.

Photochemical alterations in DNA revealed by DNA-based liquid crystals

The preparations of chicken erythrocyte linear double-stranded DNA and superhelical plasmid pBR322 DNA were irradiated by continuous low-intensity UV radiation (I = 25-50 W/m2, lambda = 254 nm) as well as by high-intensity picosecond laser UV radiation (I = 10(11)-10(13) W/m2, lambda = 266 nm). The effect of DNA secondary structure alterations on the formation of liquid-crystalline dispersions from UV-irradiated DNA preparations was studied. It was shown that in the case of linear DNA, watching the disappearance of abnormal optical activity characteristic for cholesteric liquid crystal we managed to detect the presence of photochemical alterations in DNA irradiated by low-intensity UV radiation at an absorbed energy of more than 20 quanta per nucleotide. In the case of superhelical DNA using enzyme treatment of liquid-crystalline dispersions and monitoring the appearance of abnormal optical activity, we detected the presence of photochemical alterations in DNA molecules after low-intensity UV irradiation at an absorbed energy of less than 4 quanta per nucleotide. Under the latter approach using picosecond UV laser irradiation at three different light intensities we were able to distinguish the different mechanisms of fine alterations in DNA secondary structure at an absorbed energy value of about 3 quanta per nucleotide.

High-performance liquid chromatography of the photoproducts of nucleic acid components. III. Detection of the secondary structure differences in sequence isomeric self-complementary oligonucleotides

Reversed-phase high-performance liquid chromatography (RP-HPLC) was used to detect differences in the secondary structures of two self-complementary oligodeoxyribonucleotides. The [d(CCTTTAAAGG)]2 duplex assumes an ordinary B-conformation in aqueous solution, while [d(GGAAATTTCC)]2 is known to contain in its central part a stretch of a more rigid B'-form conformation with significantly lowered fluctuational mobility of base pairs. The latter factor causes a marked difference in the amounts of thymine cyclobutane photodimers formed under UV irradiation of corresponding duplexes as revealed by chromatography of two single-stranded oligonucleotides. Increasing the temperature below the duplex melting temperature (stimulation of the B'-B structural transition) results in an increase in photodimer formation that was inhibited in the B'-form. Thus, we demonstrate the usefulness of RP-HPLC for duplex DNA structural studies.

HPLC photofingerprinting of conformational peculiarities and transitions in oligonucleotide duplexes

Two self-complementary sequence-isomeric decadeoxyribonucleotides were exposed to UV light under conditions in which they assume duplex structures. After that they were analyzed in the denatured state by reversed-phase high-performance liquid chromatography (HPLC). Characterization of the separated photoproducts allowed localization of cyclobutane pyrimidine dimers in the sequences of the modified oligonucleotides. For [d(GGAAATTTCC)]2, which is known to contain in its central part a stretch of rigid B'-conformation with decreased mobility of constituent bases, lower yields of thymine dimers, as compared with that for ordinary B-form [d(CCTTTAAAGG)]2, were found. On the contrary, mixed thymine-cytosine heterodimers generated in the former oligonucleotide demonstrate the increase in photoreactivity of these residues at the B'-B junction. This is probably due to the peculiar conformation adopted by this decanucleotide. Stimulation of B'-B transition, by increasing the temperature before melting, reduced an inhibition of thymine photodimer formation. During the melting of both oligonucleotides yields of all identified photoinduced cyclobutadipyrimidines were reduced. Possible influences of some metal cations on the stability of the B'-form were also studied by this photoprobing technique. The present study demonstrates the feasibility of HPLC photofingerprinting as a new approach for structural analysis of nucleic acids.

UV irradiation of nucleic acids: characterization of photoproducts of thymidylyl-(3'-->5')-2'-deoxy-5-fluorouridine

The acetone-sensitized irradiation using UV-B (ultraviolet light, 280-320 nm; sunlamps) of thymidylyl(3'-->5')deoxyfluorouridine monophosphate produces two main photoproducts. The distribution of these photoproducts is dependent on the pH of the irradiation solution. At pH 6, the cis-syn cyclobutane-type photodimer is the major product, whereas at high pH (8-10) a photoadduct is the major product. These photoproducts have been identified and structurally characterized by H-1 and C-13 NMR spectroscopy. The photoadduct arises from defluorination of the 5-fluorouracil moiety. The structure of the photoadduct maintains the sugar-phosphate backbone of the starting material (d-TpF), and contains a saturated thymine moiety with an added Thy(C6-hydroxyl) and a Thy(C5)-(C5)Ura covalent bond.

Substituent effects on the puckering mode of the cyclobutane ring and the glycosyl bond of cis-syn photodimers

The cyclobutane ring (CB) puckering of a cis-syn DNA photodimer (cis-syn d-T[p]T) differs from that of a cis-syn RNA photodimer (cis-syn r-U[p]U) [J.-K. Kim and J.L. Alderfer (1992) Journal of Biomolecular Structure and Dynamics, Vol. 9, p. 1705]. In cis-syn d-T[p]T, interconversion of the CB ring between CB+ and CB- is observed, while in cis-syn r-U[p]U only CB- is observed. In the CB+ conformation, the two thymine rings of the dimer are twisted in a right-handed fashion, as are the bases in B-form DNA. In case of CB- they are twisted in a left-handed fashion. The C5 (base) and/or C2' (sugar) substituents apparently affect the CB ring flexibility in cis-syn d-T[p]T and cis-syn r-U[p]U. To study the effects of the C5 substituent on CB ring flexibility, two-dimensional nuclear Overhauser effect (NOE) and 31P-nmr experiments were performed on cis-syn d-T[p]U, cis-syn d-U[p]T, and cis-syn d-U[p]U photodimers to investigate the CB puckering mode and overall molecular conformation and dynamics. The NOE results indicate the 5-methyl group in the photodimer induces conformational flexibility of the CB ring. In cis-syn d-T[p]U and cis-syn d-U[p]T, both CB+ and CB- puckering modes are observed. This indicates interconversion between two modes takes place as observed in cis-syn d-T[p]T. In the case of cis-syn d-U[p]U, only the puckering CB- mode is observed.(ABSTRACT TRUNCATED AT 250 WORDS)

Conformational variations of the cis-syn cyclobutane-type photodimer in DNA and RNA

The recent NMR study of a cis-syn photodimer B-DNA 10mer-duplex (Taylor et al., Biochemistry 29, 8858 (1990)) showed the cyclobutane (CB) ring with a puckered-twist in a right-handed sense (CB+). This is opposite to that of the crystal structure of cis-syn d-TpT(cyano-ethyl)(d-T[p]T-CE) which has a left-handed puckered-twist (CB-)(Hruska et al., Biopolymers 25, 1399 (1986)). 2D-NOESY experiments were performed on cis-syn d-T[p]T and cis-syn U[p]U at 25 and 35 degrees C, respectively, to investigate the puckering mode of the cyclobutane ring of isolated cis-syn photodimers of the DNA and RNA types. The DNA photodimers showed interconversion of the puckered-twist of the cyclobutane ring between CB- and CB+ and interconversion of the glycosidic angle between syn and anti in both nucleoside residues. Interestingly, in the RNA photodimer only the CB- puckering mode with syn conformation of the glycosidic angle of the U[p]- was observed. These different dynamical behaviors of the photodimer in DNA and RNA might portend differential conformational effects on their corresponding normal nucleic acid regions. In addition these results indicate differences in the cyclobutane ring conformation of the cis-syn d-T[p]T, not only in solution and crystalline states, but also when the dimer is isolated and in duplex forms.

Site-specific effect of thymine dimer formation on dAn.dTn tract bending and its biological implications

dAn.dTn sequences, otherwise known as A tracts, are hotspots for cis-syn thymine dimer formation and deletion mutations induced by UV light. Such A tracts are also known to bend DNA, suggesting that some biological effects of UV light might be related to the distinctive structure and properties of cis-syn dimer-containing A tracts. To investigate the effect of thymine dimer formation on A-tract bending multimers of all possible dimer monoadducts of a dA6.dT6-containing decamer known to bend DNA were prepared along with multimers of a dimer-containing 21-mer of heterogeneous sequence. The characteristic anomalous electrophoretic behavior of the phased A-tract multimers was essentially abolished by dimer formation at the center of the A tract and was only slightly reduced by dimer formation at the ends. These effects are attributed to disruption of the A-tract structure at the site of the dimer, resulting in intact A tracts of reduced length and, hence, reduced bending. This model was suggested by the ability to formulate the estimated bend angles of the dimer-containing A tracts as approximately equal to the sum of the bend angles induced by the dimer and the remaining intact portion of the A tract. Contrary to a previous experimental study that concluded that the thymine dimer bends DNA by approximately 30 degrees, the dimer was determined to bend DNA by only approximately 7 degrees. Reduction of the bending of a DNA sequence by dimer formation may have a number of unpredicted and important biological consequences.

NMR studies of bipyrimidine cyclobutane photodimers

Cyclobutane-type photodimers of dinucleoside monophosphates dCpdT, dTpdC and dTpdT were prepared by ultraviolet irradiation in the presence of acetophenone as photosensitizer. The cytosine-containing derivatives were found to deaminate forming uracil products. Using one- and two-dimensional NMR, the photoproducts were characterized as cis-syn and trans-syn cyclobutane photodimers. On the basis of NOE data the structures of the cis-syn and trans-syn products of dUpdT were determined using distance-geometry and restrained-energy-minimization methods. The cis-syn structures showed (high-ANTI/SYN)/high-ANTI glycosidic linkages while the trans-syn structures were in the SYN-ANTI region. The backbone conformations of both structures were in fair agreement with the coupling-constant-data. The trans-syn structures were found to be very rigid and similar in all three products. For the three cis-syn structures more conformational freedom and more variation among the three structures was observed.

1H NMR assignment and melting temperature study of cis-syn and trans-syn thymine dimer containing duplexes of d(CGTATTATGC).d(GCATAATACG)

The preparation and spectroscopic characterization of duplex decamers containing site-specific cis-syn and trans-syn thymine dimers are described. Three duplex decamers, d(CGTATTATGC).d(GCATAATACG), d(CGTAT[c,s]TATGC).d(GCATAATACG), and d(CGTAT[t,s]TATGC).d(GCATAATACG), were prepared by solid-phase phosphoramidite synthesis utilizing cis-syn and trans-syn cyclobutane thymine dimer building blocks (Taylor et al., 1987; Taylor & Brockie, 1988). NMR spectra (500 MHz 2D 1H and 202 MHz 1D 31P) were obtained in "100%" D2O at 10 degrees C, and 1D exchangeable 1H spectra were obtained in 10% D2O at 10 degrees C. 1H NMR assignments for H5, H6, H8, CH3, H1', H2', and H2" were made on the basis of standard sequential NOE assignment strategies and verified in part by DQF COSY data. Comparison of the chemical shift data suggests that the helix structure is perturbed more to the 3'-side of the cis-syn dimer and more to the 5'-side of the trans-syn dimer. Thermodynamic parameters for the helix in equilibrium coil equilibrium were obtained by two-state, all or none, analysis of the melting behavior of the duplexes. Analysis of the temperature dependence of the T5CH3 1H NMR signal gave delta H = 44 +/- 4 kcal and delta S = 132 +/- 13 eu for the trans-syn duplex. Analysis of the concentration and temperature dependence of UV spectra gave delta H = 64 +/- 6 kcal and delta S = 178 +/- 18 eu for the parent duplex and delta H = 66 +/- 7 kcal and delta S = 189 +/- 19 eu for cis-syn duplex. It was concluded that photodimerization of the dTpdT unit to give the cis-syn product causes little perturbation of the DNA whereas dimerization to give the trans-syn product causes much greater perturbation, possibly in the form of a kink or dislocation at the 5'-side of the dimer.

Conformational features of DNA containing a cis-syn photodimer

In an effort to understand the conformational and structural changes in DNA brought about by thymine photodimer, computer modeling and molecular mechanics energy calculations were performed on DNA hexamer and dodecamer duplexes containing a cis-syn photodimer. The conformation of the crystal structure of the cyanoethyl phosphate ester of the thymine dimer (Hruska et al., Biopolymers 25, 1399-1417 (1986)) was used in modeling the photodimer portion. Various starting conformations were used in the modeling procedure and the structures were minimized both retaining and later relaxing the crystallographic geometry of the cyclobutane ring. The results indicate that most of the deformation is restricted to the thymine dimer region, and that the conformational changes decrease rapidly on either side of the region containing the photodimer. The structural changes brought about by the introduction of the photodimer can be accommodated within six base paired duplex without significant bend in the DNA. More conformational changes are observed on the 5'-side of the photodimer than on the 3'-side. The conformational features, such as backbone torsion angles and sugar puckers, of the energy minimized structures are discussed in the context of the solution structures determined by NMR on a series of oligomers containing photodimers (Rycyna et al., Biochemistry 27, 3152-3163 (1988)).

The solution structure of the intramolecular photoproduct of d(TpA) derived with the use of NMR and a combination of distance geometry and molecular dynamics

One and two dimensional NMR techniques have been used together with molecular modelling to obtain the solution structure for the photoproduct d(TpA)*. The NMR data confirm that the cyclobutane linkage is formed between the bonds thymine C6-C5 and adenine C5-C6. The 2D NOE data are used as constraints in a distance geometry calculation. The structures obtained show a trans-syn cyclobutane linkage and the glycosidic angles are SYN and ANTI for thymidine and deoxyadenosine, respectively. The coupling constant data are used to check the backbone torsion angles of the obtained structures. Typical torsion angles are a gamma+ and beta t for the deoxyadenosine residue. A free molecular dynamics simulation of a trans-syn d(TpA) photoproduct confirmed all these structural characteristics.

Reaction of Escherichia coli and yeast photolyases with homogeneous short-chain oligonucleotide substrates

Similar rates have been observed for dimer repair with Escherichia coli photolyase and the heterogeneous mixtures generated by UV irradiation of oligothymidylates [UV-oligo(dT)n, n greater than or equal to 4] or DNA. Comparable stability was observed for ES complexes formed with UV-oligo(dT)n, (n greater than or equal to 9) or dimer-containing DNA. In this paper, binding studies with E. coli photolyase and a series of homogeneous oligonucleotide substrates (TpT, TpTp, pTpT, TpTpT, TpTpT, TpTpTpT, TpTpTpT, TpTpTpT, TpTpTpT) show that about 80% of the binding energy observed with DNA as substrate (delta G approximately 10 kcal/mol) can be attributed to the interaction of the enzyme with a dimer-containing region that spans only four nucleotides in length. This major binding determinant (TpTpTpT) coincides with the major conformational impact region of the dimer and reflects contributions from the dimer itself (TpT, delta G = 4.6 kcal/mol), adjacent phosphates (5'p, 0.8 kcal/mol; 3'p, 1.1 kcal/mol), and adjacent thymine residues (5'T, 0.8 kcal/mol; 3'T, 1.3 kcal/mol). Similar turnover rates (average kcat = 6.7 min-1) are observed with short-chain oligonucleotide substrates and UV-oligo(dT)18, despite a 25,000-fold variation in binding constants (Kd). In contrast, the ratio Km/Kd decreases as binding affinity decreases and appears to plateau at a value near 1. Turnover with oligonucleotide substrates occurs at a rate similar to that estimated for the photochemical step (5.1 min-1), suggesting that this step is rate determining. Under these conditions, Km will approach Kd when the rate of ES complex dissociation exceeds kcat.(ABSTRACT TRUNCATED AT 250 WORDS)