Vibrational fluctuations of hydrogen bonds in a DNA double helix with alternating TA type inserts.

The Green's function technique is applied to a study of breathing modes in a DNA double helix which contains a region of different base pairs from the rest of the double helix. The calculation is performed on an alternating poly(dC-dG).poly(dC-dG) helix in the B conformation with four consecutive base pairs replaced by a model of a biological promoter region with four alternating T-A,A-T base pairs, henceforth referred to as (TATA)2. The average stretch of interbase hydrogen bonds is found to be amplified around the insert. This is likely related to the (TATA)2 insert having a lower stability against hydrogen bond melting than the two semi-infinite poly(dC-dG).poly(dC-dG) helices. The insert region may be considered to be a site of enhanced tendency to melt in such a helix. The results show that an alternating AT insert of four base pairs has a larger average hydrogen bond stretch inside and outside the insert region than the average hydrogen bond stretch inside and outside an insert of four consecutive A-T base pairs, henceforth referred to as (AAAA).(TTTT). Calculations are performed which show that the enhancement of the average hydrogen bond stretch around an alternating TA type insert is greatly dependent upon the local modes and not the inband modes. The amount of local mode enhanced average stretch is explored as a function of insert size.     

Chemical consequences of incorporation of 5-fluorouracil into DNA as studied by NMR

The cytotoxic analogue of thymine, 5-fluorouracil (Uf), is known to be incorporated into DNA in biological systems. This abnormal base has been synthetically incorporated into short DNA oligomers. The ionization of the N-3 proton of this base within DNA oligomers was measured by observation of the 19F chemical shift at varying pH values. The pKa values for the Uf ring of dTpdUfpdT and dApdUfpdA were determined to be 7.84 and 7.9, respectively. The self-complementary 12-mers d(G-C-G-C-A-A-T-Uf-G-C-G-C) and d(C-G-A-T-Uf-A-T-A-A-T-C-G) were synthesized, and 1H NMR was used to compare the helix dynamics and stability of the interstrand imino proton hydrogen bonds with those of the 12-mers d(G-C-G-C-A-A-T-T-G-C-G-C) and d(C-G-A-T-T-A-T-A-A-T-C-G). The N-3 hydrogen bond of the A-Uf base pair was less stable than the corresponding hydrogen bond in A-T base pairs in the same helix, and the A-Uf base pair was less stable than the A-T base pair in the analogous position of the control helix. The observed temperature-dependent dynamics and NMR melting temperatures of the control and dUf-containing oligomers were similar.     

Degradation of nucleic acid in aqueous solution by ionizing radiation: III. The correlation of radiation damage with change in melting transition - model experiments

The melting behavior of polydeoxynucleotide double helices of known structure is analyzed in terms of the thermodynamics of helix stability, taking into account separately those contributions to the transition free energy that are proportional to the numbers of polymer molecules and those that are proportional to the numbers of base pairs formed. From the analysis of the melting transitions of helices having an alternating (d-) A-T, G-C base-pair sequence and containing either single-strand nicks or both nicks and damaged thymine bases, the effects of these structural lesions are assessed; it is concluded that, in a moderately long helix of this sequence (400 base pairs), the initial introduction of one mid-chain doublestrand break or single-strand break produces respectively some 3.5 or 4 times as much depression in the transition temperature (T_m) as does the destruction of a single internal A-T base pair.     

Spectroscopic analysis of the interaction of Escherichia coli DNA-dependent RNA polymerase with T7 DNA and synthetic polynucleotides.

We have studied the circular dichroism and ultraviolet difference spectra of T7 bacteriophage DNA and various synthetic polynucleotides upon addition of Escherichia coli RNA polymerase. When RNA polymerase binds nonspecifically to T7 DNA, the CD spectrum shows a decrease in the maximum at 272 but no detectable changes in other regions of the spectrum. This CD change can be compared with those associated with known conformational changes in DNA. Nonspecific binding to RNA polymerase leads to an increase in the winding angle, theta, in T7 DNA. The CD and UV difference spectra for poly[d(A-T)] at 4 degrees C show similar effects. At 25 degrees C, binding of RNA polymerase to poly[d(A-T)] leads to hyperchromicity at 263 nm and to significant changes in CD. These effects are consistent with an opening of the double helix, i.e. melting of a short region of the DNA. The hyperchromicity observed at 263 nm for poly[d(A-T)] is used to determine the number of base pairs disrupted in the binding of RNA polymerase holoenzyme. The melting effect involves about 10 base pairs/RNA polymerase molecule. Changes in the CD of poly(dT) and poly(dA) on binding to RNA polymerase suggest an unstacking of the bases with a change in the backbone conformation. This is further confirmed by the UV difference spectra. We also show direct evidence for differences in the template binding site between holo- and core enzyme, presumably induced by the sigma subunit. By titration of the enzyme with poly(dT) the physical site size of RNA polymerase on single-stranded DNA is approximately equal to 30 bases for both holo- and core enzyme. Titration of poly[d(A-T)] with polymerase places the figure at approximately equal to 28 base pairs for double-stranded DNA.     

Optical studies of a conformational change in DNA before melting

The circular dichroism of double-stranded DNA is temperature dependent prior to its melting. As the temperature is increased the spectrum becomes more nonconservative. This is certainly due to a conformational change within the framework of the double helix. To ascertain the nature of the conformational change, a series of synthetic and natural DNA's from a variety of sources was investigated. The same qualitative changes were seen for all the DNA samples, independent of base composition. However, there were definite quantitative differences, with poly [d(A-T)] manifesting the largest effect. Oligomers of the form [d(A-T)]_n with n = 10 to 21 behaved in a manner similar to the polymer. There is no observed chain-length dependence. The breadth of the pre-melt transition indicates a low ΔH (less than 5 kcal./mole); the lack of dependence on chain length indicates that the co-operative unit is smaller than eight base pairs.     

Nucleic acid constituent interactions

Hydrogen bonding contributes of the order of 5–15 kcal/mol base pair to the stability of the helix (electronic or intrinsic energy). This contribution is selective, i.e., there is a preferential stability of the Watson-Crick G-C pair relative to all other pairs. Stacking interactions contribute approximately of the same order as hydrogen bonding. Perhaps the most interesting aspect of the stacking interactions which emerges from the theoretical analysis is the fact that the stacking maxima are not necessarily at the angles the successive base pair plans assume in a regular double helix. Consequently some sequence dependent structure peculiarities may arise. That is, the double helix may have a fine structure contingent on the sequence of base pairs. Indeed such sequence dependent polymorphism has been reported in the recent literature and appears to influence the ability of aromatic drugs to intercalate into the helix. The solvent effect which is another factor of stability seems to decrease somewhat bonding scheme preferences. For example, in the model we used to estimate solvent effect, we find that the G-C pair formation is de-stabilized strongly in water, while the A-T pair formation is mildly enhanced. The continuum model of solvent effect leads to similar qualitative conclusions. Studies of backbone conformation indicate that only a limited range of conformational states are comparable with the helical configuration. Improved empirical methods are needed in order to successfully calculate backbone effects for relatively large segments of nucleic acids.     

Interaction of the ruthenium red cation with nucleic acid double helices

The hexapositive complex cation ruthenium red very effectively stabilizes DNA and RNA double helices against thermal denaturation. In the presence of nucleic acid helices, this symmetric cation acquires an extrinsic CD spectrum near the wavelength of the dye's maximum absorbance. Competition experiments with single-stranded polyd(T) show this induced CD to be the result of selective binding to helical sites. The preferential affinity of ruthenium red for double helical binding sites is so great that it brings about biphasic absorbance- temperature profiles of polyd(A-T) at low [cation]: [polynucleotide phosphate]. The visible CD signal and fraction of helix melting at the upper transition increases with ruthenium red concentration until approximate charge neutrality is reached. These interactions, which have been studied in detail with the poly(U-U) helix as well as polyd(A-T), are likely largely electrostatic, since sufficient [NaCl] eliminates the bipliasic melting of polyd(A-T), renders the ultraviolet absorbance of poly (U) insensitive to ruthenium red, and abolishes the induced CD effects. The bipliasic melting of polyd(A-T) at intermediate [dye] is attributed to saturation of remaining double helical segments by cation migration from newly melted regions- Furthermore, virtually no change was observed in the induced CD upon melting through the first transition, whereas the effect is destroyed upon inciting through the second transition. A quantitative treatment of the data is used to obtain binding site size and association constant for the complex. The induced effect may prove useful in the exploration of exposed nucleic acid helical structure in such complex particles as nucleosomes or ribosomes.     

Distortions induced in double-stranded oligonucleotides by the binding of cis- or trans-diammine-dichloroplatinum(II) to the d(GTG) sequence.

Conformational changes induced in double-stranded oligonucleotides by the binding of trans- or cis-diamminedichloro platinum(II) to the d(GTG) sequence have been characterized by means of melting temperatures, electrophoretic migrations in non-denaturing polyacrylamide gels, reactivities with the artificial nuclease Phenanthroline-copper and with chemical probes. The cis-platinum adduct behaves more as a centre of directed bend than as a hinge joint, the induced bend angle being of the order of 25-30 degrees. The double helix is locally denatured over 2 base pairs (corresponding to the platinated 5'G residue and the central T residue) and is distorted over 4-5 base pairs. The trans-platinum adduct behaves also more as a centre of directed bend than as a hinge joint, the induced bend angle being of the order of 60 degrees. The double helix is locally denatured over 4 base pairs (corresponding to the immediately 5'T residue adjacent to the adduct and to the three base residues of the adduct). Both the cis- and trans-platinum adducts decrease the thermal stability of the double helix.     

Melting of Cross-Linked DNA V. Cross-Linking Effect Caused by Local Stabilization of the Double Helix

Abstract

DNA interstrand cross-links are usually formed due to bidentate covalent or coordination binding of a cross-linking agent to nucleotides of different strands. However interstrand linkages can be also caused by any type of chemical modification that gives rise to a strong local stabilization of the double helix. These stabilized sites conserve their helical structure and prevent local and total strand separation at temperatures above the melting of ordinary AT and GC base pairs. This local stabilization makes DNA melting fully reversible and independent of strand concentration like ordinary covalent interstrand cross-links. The stabilization can be caused by all the types of chemical modifications (interstrand cross-links, intrastrand cross-links or monofunctional adducts) if they give rise to a strong enough local stabilization of the double helix. Our calculation demonstrates that an increase in stability by 25 to 30 kcal in the free energy of a single base pair of the double helix is sufficient for this “cross-linking effect” (i.e. conserving the helicity of this base pair and preventing strand separation after melting of ordinary base pairs). For the situation where there is more then one stabilized site in a DNA duplex (e.g., 1 stabilized site per 1000 bp), a lower stabilization per site is sufficient for the “cross-linking effect” (18–20 kcal). A substantial increase in DNA stability was found in various experimental studies for some metal-based anti-tumor compounds. These compounds may give rise to the effect described above. If ligand induced stabilization is distributed among several neighboring base pairs, a much lower minimum increase per stabilized base pair is sufficient to produce the cross-linking effect (1 bp- 24.4 kcal; 5 bp- 5.3 kcal; 10 bp- 2.9 kcal, 25 bp- 1.4 kcal; 50 bp- 1.0 kcal). The relatively weak non-covalent binding of histones or protamines that cover long regions of DNA (20–40 bp) can also cause this effect if the salt concentration of the solution is sufficiently low to cause strong local stabilization of the double helix. Stretches of GC pairs more than 25 bp in length inserted into poly(AT) DNA also exhibit properties of stabilizing interstrand cross-links.     

Melting of cross-linked DNA v. cross-linking effect caused by local stabilization of the double helix

DNA interstrand cross-links are usually formed due to bidentate covalent or coordination binding of a cross-linking agent to nucleotides of different strands. However interstrand linkages can be also caused by any type of chemical modification that gives rise to a strong local stabilization of the double helix. These stabilized sites conserve their helical structure and prevent local and total strand separation at temperatures above the melting of ordinary AT and GC base pairs. This local stabilization makes DNA melting fully reversible and independent of strand concentration like ordinary covalent interstrand cross-links. The stabilization can be caused by all the types of chemical modifications (interstrand cross-links, intrastrand cross-links or monofunctional adducts) if they give rise to a strong enough local stabilization of the double helix. Our calculation demonstrates that an increase in stability by 25 to 30 kcal in the free energy of a single base pair of the double helix is sufficient for this "cross-linking effect" (i.e. conserving the helicity of this base pair and preventing strand separation after melting of ordinary base pairs). For the situation where there is more then one stabilized site in a DNA duplex (e.g., 1 stabilized site per 1000 bp), a lower stabilization per site is sufficient for the "cross-linking effect" (18 - 20 kcal). A substantial increase in DNA stability was found in various experimental studies for some metal-based anti-tumor compounds. These compounds may give rise to the effect described above. If ligand induced stabilization is distributed among several neighboring base pairs, a much lower minimum increase per stabilized base pair is sufficient to produce the cross-linking effect (1 bp- 24.4 kcal; 5 bp- 5.3 kcal; 10 bp- 2.9 kcal, 25 bp- 1.4 kcal; 50 bp- 1.0 kcal). The relatively weak non-covalent binding of histones or protamines that cover long regions of DNA (20- 40 bp) can also cause this effect if the salt concentration of the solution is sufficiently low to cause strong local stabilization of the double helix. Stretches of GC pairs more than 25 bp in length inserted into poly(AT) DNA also exhibit properties of stabilizing interstrand cross-links.     

Nuclear magnetic resonance study of hydrogen-bonded ring protons in oligonucleotide helices involving classical and nonclassical base pairs.

A study of the exchangeable ring nitrogen protons in aqueous solutions of oligonucleotide complexes involving Watson-Crick base pairs as well as Hoogsteen pairs and other nonclassical hydrogen bonding schemes shows that resolvable resonances in the low-field (-10 to -16 ppm from sodium 4,4-dimethyl-4-silapentanesulfonate) region can be detected in a variety of structures other than double stranded helices. Ring nitrogen proton resonances arising from the following hydrogen-bonding situations are reported: (1) AT and GC Watson-Crick base pairs in a self-complementary octanucleotide, dApApApGpCpTpTpT; (2) U-A-U base triples in complexes between oligo-U15 and AMP; (3) C-G-C+ base triples in complexes between oligo-C17 and GMP at acid pH; (4) s4U-A-s4U base triples in complexes between oligo-s4U15 and AMP, all of which involve both Watson-Crick and Hoogsteen base pairing to form triplexes; (5) C-C+ base pairing between protonated and unprotonated C residues in oligo-C17 at acid pH; and (6) I4 base quadruples in the four strand association among oligo-I at high salt. The behavior of the dA3G-CT3 helix is consistent with both fraying of the terminal base pairs and presence of intermediate states as the helix opens. In the monomer-oligomer complexes, under the conditions used here, the exchange appears to be governed by the dissociation rate of monomer from the complex. These findings suggest that those tertiary structure hydrogen bonds in tRNA involving ring nitrogen protons should have representative resonances in the low-field (11-16 ppm) proton NMR region in H2O.     

Synergistic effects in the melting of DNA hydration shell: melting of the minor groove hydration spine in poly(dA).poly(dT) and its effect on base pair stability.

We propose that water of hydration in contact with the double helix can exist in several states. One state, found in the narrow groove of poly(dA).poly(dT), should be considered as frozen to the helix, i.e., an integral part of the double helix. We find that this enhanced helix greatly effects the stability of that helix against base separation melting. Most water surrounding the helix is, however, melted or disassociated with respect to being an integral part of helix and plays a much less significant role in stabilizing the helix dynamically, although these water molecules play an important role in stabilizing the helix conformation statically. We study the temperature dependence of the melting of the hydration spine and find that narrow groove nonbonded interactions are necessary to stabilize the spine above room temperature and to show the broad transition observed experimentally. This calculation requires that synergistic effects of nonbonded interactions between DNA and its hydration shell affect the state of water-base atom hydrogen bonds. The attraction of waters into narrow groove tends to retain waters in the groove and compress or strain these hydrogen bonds.     

ATP-dependent minor groove recognition of TA base pairs is required for template melting by the E1 initiator protein

Template melting is an essential step in the initiation of DNA replication, but the mechanism of template melting is unknown for any replicon. Here we demonstrate that melting of the bovine papillomavirus type 1 ori is a sequence-dependent process which relies on specific recognition of TA base pairs in the minor groove by the E1 initiator. We show that correct template melting is a prerequisite for the formation of a stable double hexamer with helicase activity and that ori mutants that fail to melt correctly are defective for ori unwinding and DNA replication in vivo. Our results also indicate that melting of the DNA is achieved by destabilization of the double helix along its length through multiple interactions with E1, each of which is responsible for melting of a few base pairs, resulting in the extensive melting that is required for initiation of DNA replication.     

Interaction between hydroxystilbamidine and DNA. I. Binding isotherms and thermodynamics of the association.

Isotherms describing the binding of hydroxystilbamidine to DNA and polydeoxyribonucleotides were obtained by means of sedimentation or dialysis experiments and fluorescence measurements, over a large range of ionic strengths, temperatures and base compositions. Two different sets of binding sites are necessary to explain the shapes of the isotherms. The first one is characterized by a higher binding constant, a topological specificity for the A-T pair, exclusion of four base pairs per bound dye molecule, the involvement of two ion-pairs, an almost purely entropic free energy of binding and a large enhancement of the blue fluorescence (450 nm) when the site corresponds to three adjacent A-T pairs. The latter does not present any specificity nor enhancement of fluorescence and only one ion-pair is formed. From the geometry of the dye and its selective binding to a double stranded structure, the hydroxystilbamidine molecule in the first set of sites is likely to be situated in the small groove astride the two complementary strands and slightly distorting the helical structure. The angle of the dye axis with the helix axis has a value close to 47 degrees. No definite explanation could be given for the specific binding of hydroxystilbamidine but the phenolic hydroxyl group is likely to play a major role. The hydroxystilbamidine molecule can be considered as a useful tool for checking the accessibility of the small groove.     

Sequence-specific recognition of DNA: NMR studies of the imino protons of a synthetic RNA polymerase promoter

We have synthesized both strands of a DNA duplex containing the consensus Pribnow promoter sequence TATAATG , flanked by GC base pairs to stabilize the ends of the helix. The stability of this duplex has been studied by using 1H nuclear magnetic resonance. The imino protons have been assigned by using the sequential nuclear Overhauser effect approach. Exchange rates have been monitored by using selective inversion recovery measurements. The helix is relatively unstable in the center of the AT-rich region even when surrounded by GC base pairs, and there is considerable asymmetry in the melting of the helix.     

Structural studies of DNA fragments: the G.T wobble base pair in A, B and Z DNA; the G.A base pair in B-DNA

The crystal structures of five double helical DNA fragments containing non-Watson-Crick complementary base pairs are reviewed. They comprise four fragments containing G.T base pairs: two deoxyoctamers d(GGGGCTCC) and d(GGGGTCCC) which crystallise as A type helices; a deoxydodecamer d(CGCGAATTTGCG) which crystallises in the B-DNA conformation; and the deoxyhexamer d(TGCGCG), which crystallises as a Z-DNA helix. In all four duplexes the G and T bases form wobble base pairs, with bases in the major tautomer forms and hydrogen bonds linking N1 of G with O2 of T and O6 of G with N3 of T. The X-ray analyses establish that the G.T wobble base pair can be accommodated in the A, B or Z double helix with minimal distortion of the global conformation. There are, however, changes in base stacking in the neighbourhood of the mismatched bases. The fifth structure, d(CGCGAATTAGCG), contains the purine purine mismatch G.A where G is in the anti and A in the syn conformation. The results represent the first direct structure determinations of base pair mismatches in DNA fragments and are discussed in relation to the fidelity of replication and mismatch recognition.     

Unusual duplex formation in purine rich oligodeoxyribonucleotides

The purine rich oligodeoxyribonucleotides 1C, d(ATGACGGAATA) and 2C, d(ATGAGCGAATA) alone exhibit highly cooperative melting transitions. Analysis of the concentration dependence of melting, and electrophoretic studies indicate that these oligomers can form an unusual purine rich offset double helix. The unusual duplex is predicted to contain four A.T, two G.C, and four G.A mismatch base pairs as well as a single A base stacked on the 3' end of each chain of the helix. Other possible models for the duplex are unlikely because they are predicted to contain many base pairs of low stability. Changing the central sequence to CGG or GGG should destabilize the duplex and this is observed. The unusual duplex of 2C is more stable than the duplex of 1C indicating that the stability of G.A base pairs is quite sensitive to the surrounding sequence. Addition of 1C and 2C to their complementary pyrimidine strands results in normal duplexes of similar stability. We feel that the unusual duplexes are significantly stabilized by the intrinsic stacking tendency of purine bases.