Conformation and dynamics of the Pribnow box region of the self-complementary d(C-G-A-T-T-A-T-A-A-T-C-G) duplex in solution

Identification of the determinant conferring permissive substrate usage in the telomere resolvase, ResT

Linear genome stability requires specialized telomere replication and protection mechanisms. A common solution to this problem in non-eukaryotes is the formation of hairpin telomeres by telomere resolvases (also known as protelomerases). These enzymes perform a two-step transesterification on replication intermediates to generate hairpin telomeres using an active site similar to that of tyrosine recombinases and type IB topoisomerases. Unlike phage telomere resolvases, the telomere resolvase from the Lyme disease pathogen Borrelia burgdorferi (ResT) is a permissive enzyme that resolves several types of telomere in vitro. However, the ResT region and residues mediating permissive substrate usage have not been identified. The relapsing fever Borrelia hermsii ResT exhibits a more restricted substrate usage pattern than B. burgdorferi ResT and cannot efficiently resolve a Type 2 telomere. In this study, we determined that all relapsing fever ResTs process Type 2 telomeres inefficiently. Using a library of chimeric and mutant B. hermsii/B. burgdorferi ResTs, we mapped the determinants in B. burgdorferi ResT conferring the ability to resolve multiple Type 2 telomeres. Type 2 telomere resolution was dependent on a single proline in the ResT catalytic region that was conserved in all Lyme disease but not relapsing fever ResTs and that is part of a 2-amino acid insertion absent from phage telomere resolvase sequences. The identification of a permissive substrate usage determinant explains the ability of B. burgdorferi ResT to process the 19 unique telomeres found in its segmented genome and will aid further studies on the structure and function of this essential enzyme.

TATA box DNA deformation with and without the TATA box-binding protein

DNA ring closure methods have been applied to TATA box DNA and its complex with the TATA box-binding protein (TBP). The J factors for cyclization (effective concentrations of one DNA end about the other) have been measured using cyclization kinetics, with and without bound TBP, for 18 DNA constructs containing the adenovirus major late promoter TATA box (TATAAAAG) separated by a variable helical phasing adapter from sequence-induced A-tract DNA bends. Six phasing lengths were used at three overall DNA lengths each. Cyclization kinetics were also measured in the absence of protein for the same set of molecules bearing a mutant TATA box (TACAAAAG). The results suggest that the TATA box DNA itself is strongly bent and anisotropically flexible, in a direction opposite to the bend induced by TBP, and that the mutant TACA box is much less bent/flexible. The bending and flexibility of the free DNA may govern the energetics of recognition of different DNA sequences by TBP, and the intrinsic bend may act to repress transcription complex assembly in the absence of TBP. The cyclization kinetics of TBP-DNA complexes in solution predict a geometry generally consistent with crystal structures, which show dramatic bending and unwinding. The novel observation of TBP-induced topoisomers suggests that this minicircle approach is able to distinguish TBP-induced unwinding from writhe (these cancel out in larger DNA), and this in turn suggests that changes in supercoiling in small topological domains can control TBP binding.

Conformational properties of the -35 region of the trp promoter in solution: comparison of the wild-type sequence with an AT transversion

The majority of the 1H NMR resonances of the protons in a tetradecamer containing the -35 region of the trp promoter d(GCTGTTGACAATTA): d(TAATTGTCAACAGC) and in the TA transversion have been assigned. The conformational properties of the nucleotides have been determined and compared in the two duplexes. Analysis of spin-spin coupling and NOEs shows that all sugar puckers are in the south domain (i.e. near C2' endo) and the glycosidic torsion angles are anti (chi approximately 110 degrees). The NMR data are consistent with the duplex being in the B family of conformations. Significant differences in chemical shifts between the two molecules were observed only for nearest neighbours to the transversion site, suggesting the absence of long range conformational effects. This was confirmed by the similarity of coupling constants and NOEs. Other properties are also not greatly affected at positions more than two base pairs from the mutation site. These results are consistent with the hypothesis that unconstrained oligonucleotides are highly flexible, and can readily accommodate significant perturbations of the local structure, such as a transversion.

Solution structure of a DNA octamer containing the Pribnow box via restrained molecular dynamics simulation with distance and torsion angle constraints derived from two-dimensional nuclear magnetic resonance spectral fitting

The DNA octamer [d(GTATAATG].[(CATATTAC)], containing the prokaryotic upstream consensus recognition sequence, has been examined via proton homonuclear two-dimensional nuclear Overhauser effect (2D NOE) and double-quantum-filtered correlation (2QF-COSY) spectra. All proton resonances, except those of H5' and H5" protons, were assigned. A temperature dependence study of one-dimensional nuclear magnetic resonance (NMR) spectra, rotating frame 2D NOE spectroscopy (ROESY), and T1 rho measurements revealed an exchange process that apparently is global in scope. Work at lower temperatures enabled a determination of structural constraints that could be employed in determination of a time-averaged structure. Simulations of the 2QF-COSY cross-peaks were compared with experimental data, establishing scalar coupling constant ranges of the individual sugar ring protons and hence pucker parameters for individual deoxyribose rings. The rings exhibit a dynamic equilibrium of N and S-type conformers with 80 to 100% populations of the latter. A program for iterative complete relaxation matrix analysis of 2D NOE spectral intensities, MARDIGRAS, was employed to give interproton distances for each mixing time. According to the accuracy of the distance determination, upper and lower distance bounds were chosen. The distance bounds define the size of a flat-well potential function term, incorporated into the AMBER force-field, which was employed for restrained molecular dynamics calculations. Torsion angle constraints in the form of a flat-well potential were also constructed from the analysis of the sugar pucker data. Several restrained molecular dynamics runs of 25 picoseconds were performed, utilizing 184 experimental distance constraints and 80 torsion angle constraints; three different starting structures were used: energy minimized A-DNA, B-DNA, and wrinkled D-DNA, another member of the B-DNA family. Convergence to similar structures obtained with root-mean-square deviations between resulting structures of 0.37 to 0.92 A for the central hexamer of the octamer. The average structure from the nine different molecular dynamics runs was subjected to final restrained energy minimization. The resulting final structure was in good agreement with the structures derived from different molecular dynamics runs and exhibited a substantial improvement in the 2D NOE sixth-root residual index in comparison with the starting structures. An approximation of the structure in the terminal base-pairs, which displayed experimental evidence of fraying, was made by maintaining the structure of the inner four base-pairs and performing molecular dynamics simulations with the experimental structural constraints observed for the termini.(ABSTRACT TRUNCATED AT 400 WORDS)

Study of structure, base-pair opening kinetics and proton exchange mechanism of the d-(AATTGCAATT) self-complementary oligodeoxynucleotide in solution

Using proton magnetic resonance, we have investigated the structure and the base-pair opening kinetics of the d-(AATTGCAATT) self-complementary duplex. All the non-exchangeable (except H5',5") and most exchangeable proton resonances have been assigned. The structure belongs to the B family. Imino proton exchange, measured by line broadening, longitudinal relaxation and magnetization transfer from water, is catalyzed by proton acceptors. The base-pair lifetimes, obtained by extrapolation of the exchange times to infinite concentration of ammonia are 2 and 3 milliseconds for internal A.Ts and 18 ms for G.C at 15 degrees C. In the absence of added catalysts, the imino proton of the first A.T base pair exchanges faster than that of the unpaired thymidine of the duplex formed by the sequence d-(AATTGCAATTT). This gives strong evidence for intrinsic exchange catalysis. The exchange of adenine amino protons from the closed state has been observed. Hence amino proton exchange is ill-suited for the investigation of base-pair opening kinetics.

Characterization of base-pair opening in deoxynucleotide duplexes using catalyzed exchange of the imino proton

Using nuclear magnetic resonance line broadening, longitudinal relaxation and magnetization transfer from water, we have measured the imino proton exchange times in the duplex form of the 10-mer d-CGCGATCGCG and in seven other deoxy-duplexes, as a function of the concentration of exchange catalysts, principally ammonia. All exchange times are catalyst dependent. Base-pair lifetimes are obtained by extrapolation to infinite concentration of ammonia. Lifetimes of internal base-pairs are in the range of milliseconds at 35 degrees C and ten times more at 0 degrees C. Lifetimes of neighboring pairs are different, hence base-pairs open one at a time. Lifetimes of d(G.C) are about three times longer than those of d(A.T). The nature of neighbors usually has little effect, but lifetime anomalies that may be related to sequence and/or structure have been observed. In contrast, there is no anomaly in the A.T base-pair lifetimes of d-CGCGA[TA]5TCGCG, a model duplex of poly[d(A-T)].poly[d(A-T)]. The d(A.T) lifetimes are comparable to those of r(A.U) that we reported previously. End effects on base-pair lifetimes are limited to two base-pairs. The low efficiency of exchange catalysts is ascribed to the small dissociation constant of the deoxy base-pairs, and helps to explain why exchange catalysis had been overlooked in the past. This resulted in a hundredfold overestimation of base-pair lifetimes. Cytosine amino proteins have been studied in the duplex of d-CGm5CGCG. Exchange from the closed base-pair is indicated. Hence, the use of an amino exchange rate to evaluate the base-pair dissociation constant would result in erroneous, overestimated values. Catalyzed imino proton exchange is at this time the safest and most powerful, if not the only probe of base-pair kinetics. We propose that the single base-pair opening event characterized here may be the only mode of base-pair disruption, at temperatures well below the melting transition.

Nuclear magnetic spectra of self complementary decanucleotides in solution; base sequence effect on the chemical shifts of nonexchangeable protons

The aim of this study was to attempt to determine the extent to which the chemical shifts of the nonexchangeable base protons of a DNA helix depend upon the base sequence. We measured the proton NMR spectra of twelve decadeoxynucleotides in order to carry out a "statistical" treatment. In the helices, the chemical shifts were found to be determined within +/- 0.04 ppm, largely by the nearest neighbor residues on the 5'-side, and to a smaller extent by the residue on the 3'-side. The theoretical chemical shift calculations reproduced very well the polymerization shifts measured for H2 protons of adenosines if the electrostatic field effect was taken into account. A fair agreement was also obtained for H8 protons of the adenosine and guanosine residues. However, theory underestimates the polarization effects of the base protons of cytidine. This discrepancy suggests that the conformation of this residue is different in the mononucleotides relative to double helices.

Proton exchange and base-pair lifetimes in a deoxy-duplex containing a purine-pyrimidine step and in the duplex of inverse sequence

Using proton relaxation and magnetization transfer from water we have measured the imino proton exchange kinetics in two dodecadeoxynucleotide duplexes. One is formed by the self-complementary sequence 5'-d(C-C-T-T-T-C-G-A-A-A-G-G), the other by the inverse sequence. The imino proton exchange rates are found to depend on the concentration of ammonia or imidazole, acting as basic catalysts of proton exchange. Extrapolation of exchange times to infinite catalyst concentration yields the base-pair lifetimes, for instance 40 milliseconds for the central G.C base-pair of the 5'-d(C-C-T-T-T-C-G-A-A-A-G-G) duplex and four milliseconds for its A.T neighbour, at 15 degrees C. These results differ markedly from those reported by other laboratories for similar deoxy compounds. An explanation of the discrepancy has been proposed recently. Differences between base-pair lifetimes indicate that opening is not co-operative. From the catalyst efficiency relative to exchange from isolated nucleosides, we estimate the dissociation constant of each base-pair, e.g. 0.3 x 10(-6) and 1.5 x 10(-5) at 15 degrees C, for the same G.C and A.T base-pairs. The lifetime and dissociation constant of corresponding base-pairs of the two duplexes are similar, except for the central G.C base-pair. This correlates with differences in the solution structures reported by others. We have completed the assignments of the imino protons and of the six cytosine amino protons of the 5'-d(G-G-A-A-A-G-C-T-T-T-C-C) 12-mer. A new base-pair numbering scheme is proposed.

DNA and RNA: NMR studies of conformations and dynamics in solution

The early NMR research on nucleic acids was of a qualitative nature and was restricted to partial characterization of short oligonucleotides in aqueous solution. Major advances in magnet design, spectrometer electronics, pulse techniques, data analysis and computational capabilities coupled with the availability of pure and abundant supply of long oligonucleotides have extended these studies towards the determination of the 3-D structure of nucleic acids in solution.

Influence of the base sequence on the conformational behaviour of DNA polynucleotides in solution

NMR studies were carried out on samples of the non-self-complementary tetramers d(C-A-C-A), d(T-G-T-G), d(G-A-G-A) and d(T-C-T-C) and of 1:1 mixtures of the complementary tetramers d(C-A-C-A) X d(T-G-T-G) and d(G-A-G-A) X d(T-C-T-C) at two DNA concentrations and of the self-complementary octamers d(C-A-C-A-T-G-T-G) and d(G-A-G-A-T-C-T-C). Assignments, based upon one-dimensional NOE and homonuclear-decoupling and two-dimensional correlated and NOE spectroscopies are given of the resonances of most of the base and sugar protons. Chemical shift vs temperature profiles, constructed for all samples, yielded insight into the temperature- and concentration-dependent conformational behaviour of the compounds and were used to obtain thermodynamic parameters pertaining to the stacked-single-strand----random-coil and duplex----random-coil equilibria. Vicinal proton-proton couplings were analyzed in terms of the conformation of the deoxyribose rings in the single-stranded tetramers and duplexed octamers. The NOE patterns, chemical shift profiles, imino-proton resonances and coupling data revealed that the compounds adopt B-DNA-like structures. The ratio duplexed/stacked-single-strand/random coil depends upon external conditions as well as upon base sequence. The thermodynamic data indicate that: in terms of single-helical stacking, the R-R steps (Tm 321-328 K) appear more stable than the Y-R or R-Y steps (Tm 308-316 K) and the Y-Y steps score least (Tm 290-300 K), and the duplexes consisting of alternating, d(Y-R)n, strands are more stable, in terms of delta H degrees, compared to the d(R-R)n X d(Y-Y)n duplexes. The analyses of the couplings demonstrated that the sugars of the single-stranded tetramers and duplexed octamers occur as a blend of N- and S-type conformers, with a preference for the S-type (C2'-endo) sugar conformation: upon duplex formation, no significant shift in the N-type/S-type ratio was observed. The fraction S-type sugar conformation of a given residue, %S, in the stacked-single strands was found to depend upon the nature of its own base and that of the adjacent residues: sugars in an R-R stretch display high values of %S (90-100), whereas those in Y-Y stretches show relatively low values (approximately equal to 65).(ABSTRACT TRUNCATED AT 400 WORDS)

A dominant influence of flanking sequences on a local structural transition in DNA

We have discovered a striking dependence of a structural transition in DNA on sequences that are distanced from those directly participating in the transformation. The dominant factor determining the selection of kinetic properties of cruciform extrusion is the sequence of the DNA that flanks the inverted repeat. The sequence of the inverted repeat itself appears to have little or no influence. The critical sequences that confer the unusual kinetics exhibited by the ColE1 cruciform are very A+T-rich. A single such sequence is sufficient, which may be as short as 100 bp, and it can control inverted repeats placed at either end. The effects operate in cis, are independent of polarity, and may be effective over relatively long distances. The influence of context has wide implications, possibly including the control of gene expression.