Static and Dynamic Conformational Properties of AT sequences in B-DNA

Abstract

A theoretical study of the optimal conformations of nucleic acid oligomers containing tracts of AT base pairs is presented. The oligomers are studied in isolation and complexed with netropsin, a minor groove binding ligand. The flexibility of the oligomers and of their complexes is calculated by adiabatic mapping with respect to the total winding angle. The results of this study show that in uncomplexed oligomers the dinucleotide junctions AA, AT and TA have very different structural parameters and different responses to winding stress. The TA junction is clearly the most flexible and is the principal site for accommodating the imposed overwinding. Complexation by netropsin leads to two important effects: firstly, the three junctions adopt more uniform structures, the largest changes again being observed for TA, secondly, the differences in flexibility as a function of sequence are strongly attenuated.     

Binding of non-intercalating antibiotics to B-DNA: a theoretical study taking into account nucleic acid flexibility

A detailed theoretical study has been made for five antibiotics which all bind selectively to AT sequences in the minor groove of B-DNA: SN-18071, NSC-101327, distamycin-2, distamycin-3 and netropsin. The optimal complexes were found for systems in which the flexibility of DNA, as well as that of the antibiotics, was taken into account. Explicit, mobile counterions and a dielectric function modelling aqueous solution were also included. The binding geometries of the most strongly interacting antibiotics, distamycin-3 and netropsin, are compared in considerable detail and it is shown that notable differences exist between them. The results for netropsin are also discussed in the light of recent disagreements concerning its exact binding location within DNA.     

Binding of Non-Intercalating Antibiotics to B-DNA: A Theoretical Study Taking Into Account Nucleic Acid Flexibility

Abstract

A detailed theoretical study has been made for five antibiotics which all bind selectively to AT sequences in the minor groove of B-DNA: SN-18071, NSCT-101327, distamycin-2, distamycin-3 and netropsin. The optimal complexes were found for systems in which the flexibility of DNA, as well as that of the antibiotics, was taken into account. Explicit, mobile counterions and a dielectric function modelling aqueous solution were also included. The binding geometries of the most strongly interacting antibiotics, distamycin-3 and netropsin, are compared in considerable detail and it is shown that notable differences exist between them. The results for netropsin are also discussed in the light of recent disagreements concerning its exact binding location within DNA.     

Theoretical studies of the selective binding to DNA of two non-intercalating ligands: netropsin and SN 18071.

A theoretical study of the binding to DNA of netropsin and a bisquaternary ammonium heterocycle, SN 18071, is undertaken with an energy minimizing program based on empirical potential functions. The positioning of the ligand is achieved by force and torque calculations and its internal flexibility is taken into account. The binding preference of both drugs studied for the AT minor groove of B-DNA is shown to depend on both the electrostatic potential generated by the base sequence and the quality of the steric fit of the ligand in the groove. Ligand-DNA hydrogen bonds are shown to aid binding, but not to be essential in establishing binding preferences.     

A theoretical study of the sequence specificity in binding of lexitropsins to B-DNA

A theoretical study is presented on the binding to B-DNA of a series of lexitropsins, these ligands being netropsin derivatives in which one or both of the pyrrole rings have been replaced by imidazoles. The best complexes have been located by energy minimisation taking into account nucleic acid flexibility, ligand flexibility, explicit, mobile counterions and solvent dielectric effects. Calculations have been performed for two homopolymeric DNA receptor sequences, AT base sequence, which only decreases in the imidazole derivatives. These results emphasize the decisive role of the molecular electrostatic potential of the nucleic acid in determining the sequence selectivity of these ligands, as opposed to the postulated role of adenine C2 - pyrrole beta hydrogen contacts.     

A Theoretical Study of the Sequence Specificity in Binding of Lexitropsins to B-DNA

Abstract

A theoretical study is presented on the binding to B-DNA of a series of lexitropsins, these ligands being netropsin derivatives in which one or both of the pyrrole rings have been replaced by imidazoles. The best complexes have been located by energy minimisation taking into account nucleic acid flexibility, ligand flexibility, explicit, mobile counterions and solvent dielectric effects. Calculations have been performed for two homopolymeric DNA receptor sequences, AT and GC. All the compounds studied exhibit an overall binding preference for the AT base sequence, which only decreases in the imidazole derivatives. These results emphasize the decisive role of the molecular electrostatic potential of the nucleic acid in determining the sequence selectivity of these ligands, as opposed to the postulated role of adenine C2 - pyrrole β hydrogen contacts.     

Oligodeoxynucleotide folding in solution: loop size and stability of B-hairpins

The secondary structures of the synthetic DNA fragments d(CGCGCGTTTTTCGCGCG) (T5), d(CGCGCGAAAAACGCGCG) (A5), d(CGCGCGTACGCGCG) (TA), and d(CGCGCGATCGCGCG) (AT) were investigated in a combined electrophoretic and spectroscopic study. All the oligomers exist, at low temperature and over a wide range of ionic strength (0.5-100 mM salt) and of nucleotide concentration [0.1-2.0 mM (phosphate)], as a mixture of two slowly interconverting species, identified as the dimeric duplex and the monomeric hairpin structure. The thermodynamic parameters for hairpin denaturation of T5, A5, TA, and AT and for duplex denaturation of d(CGCGCG) show that (a) the hairpins are more stable than the reference hexamer duplex at all accessible nucleotide concentrations; (b) the loop contributes favorably to the enthalpy change of hairpin denaturation in the four DNA fragments; (c) the base composition of the loop (A vs T) and the size of the loop (A5/T5 vs TA/AT) do not appreciably influence the enthalpic contents of the hairpins; (d) hairpins TA and AT, with two AT bases intervening in the CG self-complementary part of the molecule, exhibit a markedly higher thermal stability than hairpins T5 and A5, which is entropic in origin. These findings are consistent with the presence of two-residue loops in the tetradecamers TA and AT.     

Duplex structure formation between oligo(dA)''s and oligo(dT)''s generated by thymine-specific interaction with netropsin.

The formation of oligomeric duplex molecules in the presence of the antibiotic netropsin in the series p(dA)n-p(dT)n is demonstrated using low-temperature CD measurements. Addition of Netropsin to mixtures of oligomers generates the same type of CD spectra as observed for poly(dA)-poly(dT) and maintains the duplex structure at temperatures at which base pairing of free oligomers is thermodynamically unstable. The shortest chain length forming a netropsin complex by thymine-specific interaction with the oligopeptide is represented by p(dA)4-p(dt)4. Studies with sequence isomers show that adjacent thymine residues strongly favour the complex formation with the oligopeptide.     

Probing the hydration of the minor groove of A.T synthetic DNA polymers by volume and heat changes

The minor-groove ligand netropsin provides a sensitive probe of the hydration difference between poly(dA).poly(dT) and poly[d(AT)].poly[d(AT)]. We have measured the volume change delta V accompanying binding of netropsin to these polymers, using an improved magnetic suspension densimeter. For poly(dA).poly(dT) we find delta V = +97 mL/mol of bound netropsin at pH 7.0 and 10 mM sodium phosphate buffer. For poly[d(AT)].poly[d(AT)] we find delta V = -16 mL/mol of bound netropsin. This striking differential effect suggests that the poly(dA).poly(dT) duplex compresses more water (or is more extensively hydrated). From our enthalpy and entropy results we estimate the approximately 10 water molecules, immobilized in the minor groove of this system, are displaced by each netropsin bound. The volume increase, however, is substantially larger than can be explained by a simple melting of these immobilized water molecules in the minor groove. A decompression of at least 40 water molecules must attend the complexation to the poly(dA).poly(dT) duplex. This suggests that the conformation change attending the binding of the drug to this polymer duplex causes a further dehydration, whereas no such change in dehydration and configuration for the heteropolymer system is indicated.     

Binding of netropsin to DNA and synthetic polynucleotides

The interaction of netropsin with DNA and synthetic polydeoxyribonucleotides was studied by absorption spectrophotometry and circular dichroism. The results are consistent with a model in which a netropsin molecule occupies five base pairs in binding and carries three reaction sites each capable of interacting with one AT base pair. We associate these reaction sites with the antibiotic peptide groups which probably interact with AT base pairs by a hydrogen bonding mechanism.     

DNA flexibility as a function of allomorphic conformation and of base sequence.

Systematic theoretical modeling of symmetric DNA oligomers, carried out earlier for the B conformation, is now extended to A-DNA. In contrast to the previous results, it is found that A-DNA shows no multiplicity of low-energy substate conformations. The possibilities of the Jumna algorithm are subsequently applied to studying deformations of the oligomers. Controlled winding and stretching deformations are used to study how the two allomorphs and different base sequences absorb such external stress. The results help explain the internal mechanics of the DNA double helix and the extent to which fine structure influences this behavior. The results point to some differences between the A and B double helices, but also to many similarities. Sequence effects on flexibility are relatively limited compared to their impact on optimal energy conformations. It is also shown that the conformational substates detected for B-DNA oligomers are preserved under deformation, but have little influence on its energetics.     

Propeller-Twisting of Base-pairs and the Conformational Mobility of Dinucleotide Steps in DNA

When DNA is bent around a protein, it must distort. The distortion occurs by changes in the conformation of successive dinucleotide steps. Bending does not necessarily occur uniformly: some steps might remain particularly rigid, i.e. they might deform relatively little, while others might take more than their proportional share of deformation. We investigate here the deformational capacity of specific dinucleotide steps by examining a database of crystallized oligomers. Dividing the steps into ten types by sequence (AA(=TT), AC(=GT), AG(=CT), AT, CA(=TG), CG, GA(=TC), GC, GG(=CC) and TA), we find that some step types are practically rigid, while others have considerable internal mobility or conformational flexibility. Now in general base-pairs are not planar, but have Propeller-Twist. We find a clear empirical correlation between the level of Propeller-Twist in the base-pairs and the flexibility of the dinucleotide step which they constitute. Propeller-Twist in the base-pairs makes stacking into a dinucleotide step more awkward than in plane base-pairs. In particular, it provides a stereochemical “locking” effect which can make steps with highly Propeller-Twisted base-pairs rigid. Although the origins of Propeller-Twist are not yet clearly understood, this result provides a key to understanding the flexibility of DNA in bending around proteins.     

Specific protection of DNA by distamycin A, netropsin and bis-netropsins against the action of DNAse I

Interaction of netropsin, distamycin A and a number of bis-netropsins with DNA fragments of definite nucleotide sequence was studied by footprinting technique. The nuclease protection experiments were made at fixed DNA concentration and varying ligand concentrations. The affinity of ligand for a DNA site was estimated from measurements of ligand concentration that causes 50% protection of the DNA site. Distribution pattern of the protected and unprotected regions along the DNA fragment was compared with the theoretically expected arrangement of the ligand along the same DNA. The comparison led us to the following conclusions: 1. Footprinting experiments show that at high levels of binding the arrangement of netropsin molecules along the DNA corresponds closely to the distribution pattern expected from theoretical calculations based on the known geometry of netropsin--DNA complex. However, the observed differences in the affinity of netropsin for various DNA sequences is markedly greater than that expected from theoretical calculations. 2. Netropsin exhibits a greater selectivity of binding than that expected for a ligand with three specific reaction centers associated with the antibiotic amide groups. It binds preferentially to DNA regions containing four or more successive AT pairs. Among 13 putative binding sites for netropsin with four or more successive AT pairs there are 11 strong binding sites and two weaker sites which are occupied at 2 D/P less than or equal to 1/9 and 2 D/P = 1/4, respectively. 3. The extent of specificity manifested by distamycin A is comparable to that shown by netropsin although the molecule of distamycin A contains four rather than three amide groups. At high levels of binding distamycin A occupies the same binding sites on DNA as netropsin does. 4. The binding specificity of bis-netropsins is greater than that of netropsin. Bis-netropsins can bind to DNA in such a way that the two netropsin-like fragments are implicated in specific interaction with DNA base pairs. However, the apparent affinity of bis-netropsins estimated from footprinting experiments is comparable with that of netropsin for the same DNA region. 5. At high levels of binding bis-netropsins and distamycin A (but not netropsin) can occupy any potential site on DNA irrespectively of the DNA sequence. 6. Complex formation with netropsin increases sensitivity to DNase I at certain DNA sites along with the protection effect observed at neighboring sites.     

The solvation contribution to the binding energy of DNA with non-intercalating antibiotics.

The influence of the solvent on the binding energies to DNA of six non-intercalating antibiotics - netropsin, distamycin-3, distamycin-2, SN 18071, berenil and stilbamidine - is evaluated by combining the effect of the first hydration shell with that of bulk water. The first effect is computed by a methodology based on a spherical/point dipole model of water and limited to electrostatic interaction energies. Hydration shells are obtained which are energy optimized with respect to both water-solute and water-water interactions for the complexes and for the isolated DNA oligomers and ligands. The method allows even very large complexes to be studied in reasonable computation times. The second effect is introduced via a cavity treatment. It is shown that if the vacuum interaction energies already predict correctly the preference of the ligands for the minor groove of AT sequences of B-DNA, the introduction of the solvation effect is indispensable for reproducing the order of affinity of the ligands and for bringing the values of the complexation energies into close agreement with experimental data.     

Binding of mithramycin to DNA in the presence of second drugs

Comparative DNA equilibrium binding studies with mithramycin (MTR) and ethidium bromide in the presence and in the absence of second drugs were investigated by spectral titrations. Unusual curvatures (in contrast to those due to neighbor exclusion or anticooperativity) are found in the Scatchard plots of MTR-DNA titrations in the presence of netropsin, a minor-groove binder. Parallel studies with ethidium bromide indicate that although the presence of netropsin significantly reduces the binding ability of ethidium, no unusually curved Scatchard plots are obtained. The unusual curvature exhibited by the Scatchard plots of MTR titrations in the presence of netropsin indicates that the binding of netropsin greatly affects the MTR binding to DNA and can be simulated by an explicit incorporation of the second drug-DNA interaction in the binding formalism. Since netropsin is a minor-groove binder, its interference with the binding of MTR is in accord with the notion that MTR also binds at this groove. The observation of negligible effects on the DNA binding ability of MTR in the presence of either a major-groove or a phosphate group binder lends further support to this conclusion. Consistent with its guanine specificity, studies with synthetic polynucleotides suggest that MTR exhibits negligible affinity for poly(dA-dT).poly(dA-dT) or poly(dA).poly(dT).(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of netropsin on yeast mitochondria

Netropsin binds tightly to AT rich regions of DNA and correspondingly is an efficient inhibitor of mitochondrial DNA replication in $\text{Saccharomyces}\text{cerevisiae}$. Netropsin treatment does not cause formation of large populations of petite cells. However, a large portion of cells grown in cultures with ethanol as carbon source are killed by 1 μg/ml netropsin. When petite induction by berenil or ethidium bromide is carried out in the presence of netropsin, the petite cells are killed. This appears to be an effect of netropsin action on the cells during the process of petite formation.     

The B-Z conformational transition in folded oligodeoxynucleotides: loop size and stability of Z-hairpins

The capacity to assume a left-handed conformation and the thermodynamics of loop formation in concentrated aqueous NaClO4 have been investigated for the following palindromic sequences: d-(CGCGCGAAAAACGCGCG) (A5), d(CGCGCGTTTTTCGCGCG) (T5), d(CGCGCGTACGCGCG) (TA), and d(CGCGCGATCGCGCG) (AT). The results show that (a) each oligomer assumes a Z conformation upon exposure to increasing NaClO4 concentrations; the salt concentration at the transition midpoint is 1.8 M for both A5 and T5 and 3 and 3.5 M for TA and AT, respectively; (b) in high salt the four oligomers exist, over a wide range of nucleotide concentrations (up to 10(-3) M) and of temperature (greater than 0 degrees C), as unimolecular hairpin structures; (c) hairpins TA and AT exhibit, in buffer A, a lower thermal stability with respect to A5 and T5 (delta T about 16 degrees C), contrary to what is observed at low ionic strength; (d) on hairpin formation, the enthalpic term is about -52 kcal/mol for the two 17-mers and -38 kcal/mol for the two 14-mers, while the change in entropy is found to be around -150 eu for A5 and T5 and -115 eu for TA and AT. This thermodynamic picture suggests that a two-residue loop for TA and AT, found at low ionic strength [see preceding paper (Xodo, L.E., Manzini, G., Quadrifoglio, F., van der Marel, G.A., & van Boom, J.H. (1988) Biochemistry (preceding paper in this issue)], is substituted by a longer one including two additional residues from a missing dC.dG base pairing at the top of the stem.     

Uranyl photoprobing of nonbent A/T- and bent A-tracts. A difference of flexibility?

In this study, we have systematically compared the uranyl photocleavage of a range of bent A-tracts and nonbent TA-tracts as well as interrupted A-tracts. We demonstrate that uranyl photocleavage of A-tracts and TA-tracts is almost identical, indicating a very similar minor groove conformation. Furthermore, a 10 base pair A-tract is divided into two independent tracts by an intervening TA or GC step. Uranyl probing also clearly distinguishes the bent A4T4 and the nonbent T4A4 sequences as adopting different structures, and our interpretation of the data is consistent with a structure for the bent A4T4 sequence that resembles a continuous A-tract, whereas the nonbent T4A4 sequences are closer to two independent and opposite A-tracts that cancel each other in terms of macroscopic bending. Finally, we also note that even single TA and TAT steps are highly sensitive to uranyl photocleavage and propose that in addition to average minor groove width, uranyl also senses DNA helix flexibility/deformability. Thus, the structural difference of TA-tracts and A-tracts may to a large extent reflect a difference in flexibility, and DNA curvature may consequently require a rigid narrow minor groove conformation that creates distinct A-tract-B-DNA junctions as the predominant cause of the bending.     

The compatibility of netropsin and actinomycin binding to natural deoxyribonucleic acid.

The simultaneous binding of netropsin and actinomycin to four natural DNAs was studied to determine the influence of one ligand on the binding of the other. Actinomycin binds specifically to GC sites, whereas netropsin binds specifically to AT sites. Spectral titrations, thermal denaturation, and analytical buoyant density centrifugation were employed to measure the binding interference of these drugs. The binding of actinomycin to DNA was decreased by the presence of netropsin. Increasing the GC content of the DNA resulted in a decreased effect of netropsin on actinomycin binding. Quantitative analysis of the binding parameters indicated that netropsin and actinomycin can bind in close proximity along the DNA chain. Supercoiled DNA gave the same result as linear DNA. These results imply that DNA can absorb alterations in conformation within a short distance.     

Calorimetric and spectroscopic investigation of drug-DNA interactions. I. The binding of netropsin to poly d(AT)

We report the first calorimetric investigation of netropsin binding to poly d(AT). Temperature-dependent uv absorption, circular dichroism (CD), batch calorimetry, and differential scanning calorimetry (DSC) were used to detect, monitor, and thermodynamically characterize the binding process. The following results have been obtained: 1) Netropsin groove binding is accompanied by a large exothermic enthalpy of 9.2 kcal/mol of drug bound at 25 degrees C. This indicates that a large negative binding enthalpy may be a necessary but not a sufficient criterion for drug intercalation. We suggest that the exothermic binding might be correlated with specific H-bonding interactions. 2) From the difference in DSC transition enthalpies in the presence and absence of netropsin, we calculate a binding enthalpy of -10.7 kcal/mol of netropsin at 88 degrees C. 3) We calculate a positive delta S for netropsin binding to poly d(AT) at 25 degrees C. This positive entropy change may reflect netropsin-induced release of condensed cations and/or bound water. 4) The netropsin-saturated duplex monophasically melts 46 degrees C higher than the free duplex. The unsaturated duplex melts through two thermally-resolved transitions that correspond to netropsin-free and netropsin-bound regions. These two regions interact dynamically with no substantial influence on the thermal stabilities of the separate domains. 5) Netropsin binding decreases the cooperativity of the duplex to single strand transition.