Characterization of a novel DNA minor-groove complex

Many dicationic amidine compounds bind in the DNA minor groove and have excellent biological activity against a range of infectious diseases. Para-substituted aromatic diamidines such as furamidine, which is currently being tested against trypanosomiasis in humans, and berenil, which is used in animals, are typical examples of this class. Recently, a meta-substituted diamidine, CGP 40215A, has been found to have excellent antitrypanosomal activity. The compound has a linear, conjugated linking group that can be protonated under physiological conditions when the compound interacts with DNA. Structural and molecular dynamics analysis of the DNA complex indicated an unusual AT-specific complex that involved water-mediated H-bonds between one amidine of the compound and DNA bases at the floor of the minor groove. To investigate this unique system in more detail DNase I footprinting, surface plasmon resonance biosensor techniques, linear dichroism, circular dichroism, ultraviolet-visible spectroscopy, and additional molecular dynamics simulations have been conducted. Spectrophotometric titrations of CGP 40215A binding to poly(dAT)(2) have characteristics of DNA-binding-induced spectral changes as well as effects due to binding-induced protonation of the compound linker. Both footprinting and surface plasmon resonance results show that this compound has a high affinity for AT-rich sequences of DNA but very weak binding to GC sequences. The dissociation kinetics of the CGP 40215A-DNA complex are much slower than with similar diamidines such as berenil. The linear dichroism results support a minor-groove complex for the compound in AT DNA sequences. Molecular dynamics studies complement the structural analysis and provide a clear picture of the importance of water in mediating the dynamic interactions between the ligand and the DNA bases in the minor groove.     

DNA minor-groove recognition by 3-methylthiophene/pyrrole pair

Hairpin polyamides are synthetic oligomers, which fold and bind to specific DNA sequences in a programmable manner. Internal side-by-side pairings of the aromatic amino acid residues 1-methyl-1H-pyrrole (Py), 1-methyl-1H-imidazole (Im), and 3-hydroxy-1-methyl-1H-pyrrole (Hp) confer the ability to distinguish between all four Watson-Crick base pairs in the minor groove of B-form DNA. In a broad search to expand the heterocycle repertoire, we found that when 3-methylthiophene (Tn), which presents a S-atom to the minor groove, is paired with Py, it exhibits a modest threefold specificity for TA>AT presumably by shape-selective recognition. In this study, we explore the scope and limitations of this lead by incorporating multiple Tn residues within a single hairpin polyamide. It was found that hairpin polyamides containing more that one Tn/Py pair exhibit lowered affinities and specificities for their match sites. It appears that little deviation is permissible from the parent five-membered ring 1-methyl-1H-pyrrole-2-carboxamide scaffold for DNA recognition.     

A thermodynamic and structural analysis of DNA minor-groove complex formation

As part of an effort to develop a better understanding of the structural and thermodynamic principles of DNA minor groove recognition, we have investigated complexes of three diphenylfuran dications with the d(CGCGAATTCGCG)(2) duplex. The parent compound, furamidine (DB75), has two amidine substituents while DB244 has cyclopentyl amidine substituents and DB226 has 3-pentyl amidines. The structure for the DB244-DNA complex is reported here and is compared to the structure of the DB75 complex. Crystals were not obtained with DB226 but information from the DB75 and DB244 structures as well as previous NMR results on DB226 indicate that all three compounds bind in the minor groove at the AATT site of the duplex. DB244 and DB75 penetrate to the floor of the groove and form hydrogen bonds with T8 on one strand and T20 on the opposite strand while DB226 forms a complex with fewer interactions. Binding studies by surface plasmon resonance (SPR) yield -delta G degrees values in the order DB244>DB75>DB226 that are relatively constant with temperature. The equilibrium binding constants for DB244 are 10-20 times greater than that for DB226. Isothermal titration calorimetric (ITC) experiments indicate that, in contrast to delta G degrees, delta H degrees varies considerably with temperature to yield large negative delta Cp degrees values. The thermodynamic results, analyzed in terms of structures of the DNA complexes, provide an explanation of why DB244 binds more strongly to DNA than DB75, while DB266 binds more weakly. All three compounds have a major contribution to binding from hydrophobic interactions but the hydrophobic term is most favorable for DB244. DB244 also has strong contributions from molecular interactions in its DNA complex and all of these factors combine to give it the largest-delta G degrees for binding. Although the factors that influence the energetics of minor groove interactions are varied and complex, results from the literature coupled with those on the furan derivatives indicate that there are some common characteristics for minor groove recognition by unfused heterocyclic cations that can be used in molecular design.     

Human DNA polymerase iota promotes replication through a ring-closed minor-groove adduct that adopts a syn conformation in DNA

Acrolein, an alpha,beta-unsaturated aldehyde, is generated in vivo as the end product of lipid peroxidation and from oxidation of polyamines. The reaction of acrolein with the N2 group of guanine in DNA leads to the formation of a cyclic adduct, gamma-hydroxy-1,N2-propano-2'-deoxyguanosine (gamma-HOPdG). Previously, we have shown that proficient replication through the gamma-HOPdG adduct can be mediated by the sequential action of human DNA polymerases (Pols) iota and kappa, in which Poliota incorporates either pyrimidine opposite gamma-HOPdG, but Polkappa extends only from the cytosine. Since gamma-HOPdG can adopt either a ring-closed cyclic form or a ring-opened form in DNA, to better understand the mechanisms that Pols iota and kappa employ to promote replication through this lesion, we have examined the ability of these polymerases to replicate through the structural analogs of gamma-HOPdG that are permanently either ring closed or ring opened. Our studies with these model adducts show that whereas the ring-opened form of gamma-HOPdG is not inhibitory to synthesis by human Pols eta, iota, or kappa, only Poliota is able to incorporate nucleotides opposite the ring-closed form, which is known to adopt a syn conformation in DNA. From these studies, we infer that (i) Pols eta, iota, and kappa have the ability to proficiently replicate through minor-groove DNA lesions that do not perturb the Watson-Crick hydrogen bonding of the template base with the incoming nucleotide, and (ii) Poliota can accommodate a minor-groove-adducted template purine which adopts a syn conformation in DNA and forms a Hoogsteen base pair with the incoming nucleotide.     

Visualisation of extensive water ribbons and networks in a DNA minor-groove drug complex.

The crystal structure is reported of a complex between an ethyl derivative of the minor-groove drug furamidine and the dodecanucleotide duplex d(CGCGAATTCGCG)2, which has been refined to 1.85 A resolution and an R factor of 16.6% for data collected at -173 degreesC. An exceptionally large number (220) of water molecules have been located. The majority of these occur in the first coordination shell of solvation. There are extensive networks of connected waters, both in the major and minor grooves. In particular, there are 21 water molecules associated with the minor-groove drug, via hydrogen bonds from the four charged nitrogen atoms. One cluster of four waters is situated in the groove itself; the majority are on the outer edge of the groove, and serve to bridge between the outward-directed drug nitrogen atoms and backbone phosphate oxygen atoms. These bridges are both intra- and inter-strand, with the net effect that the outer edge of the drug molecule is covered by ribbons of water molecules.     

Configurational entropy change of netropsin and distamycin upon DNA minor-groove binding

Binding of a small molecule to a macromolecular target reduces its conformational freedom, resulting in a negative entropy change that opposes the binding. The goal of this study is to estimate the configurational entropy change of two minor-groove-binding ligands, netropsin and distamycin, upon binding to the DNA duplex d(CGCGAAAAACGCG).d(CGCGTTTTTCGCG). Configurational entropy upper bounds based on 10-ns molecular dynamics simulations of netropsin and distamycin in solution and in complex with DNA in solution were estimated using the covariance matrix of atom-positional fluctuations. The results suggest that netropsin and distamycin lose a significant amount of configurational entropy upon binding to the DNA minor groove. The estimated changes in configurational entropy for netropsin and distamycin are -127 J K(-1) mol(-1) and -104 J K(-1) mol(-1), respectively. Estimates of the configurational entropy contributions of parts of the ligands are presented, showing that the loss of configurational entropy is comparatively more pronounced for the flexible tails than for the relatively rigid central body.     

Atomic resolution of short-range sliding dynamics of thymine DNA glycosylase along DNA minor-groove for lesion recognition

Thymine DNA glycosylase (TDG), as a repair enzyme, plays essential roles in maintaining the genome integrity by correcting several mismatched/damaged nucleobases. TDG acquires an efficient strategy to search for the lesions among a vast number of cognate base pairs. Currently, atomic-level details of how TDG translocates along DNA as it approaches the lesion site and the molecular mechanisms of the interplay between TDG and DNA are still elusive. Here, by constructing the Markov state model based on hundreds of molecular dynamics simulations with an integrated simulation time of ∼25 μs, we reveal the rotation-coupled sliding dynamics of TDG along a 9 bp DNA segment containing one G·T mispair. We find that TDG translocates along DNA at a relatively faster rate when distant from the lesion site, but slows down as it approaches the target, accompanied by deeply penetrating into the minor-groove, opening up the mismatched base pair and significantly sculpturing the DNA shape. Moreover, the electrostatic interactions between TDG and DNA are found to be critical for mediating the TDG translocation. Notably, several uncharacterized TDG residues are identified to take part in regulating the conformational switches of TDG occurred in the site-transfer process, which warrants further experimental validations.     

Efficient and error-free replication past a minor-groove DNA adduct by the sequential action of human DNA polymerases iota and kappa

DNA polymerase iota (Poliota) is a member of the Y family of DNA polymerases, which promote replication through DNA lesions. The role of Poliota in lesion bypass, however, has remained unclear. Poliota is highly unusual in that it incorporates nucleotides opposite different template bases with very different efficiencies and fidelities. Since interactions of DNA polymerases with the DNA minor groove provide for the nearly equivalent efficiencies and fidelities of nucleotide incorporation opposite each of the four template bases, we considered the possibility that Poliota differs from other DNA polymerases in not being as sensitive to distortions of the minor groove at the site of the incipient base pair and that this enables it to incorporate nucleotides opposite highly distorting minor-groove DNA adducts. To check the validity of this idea, we examined whether Poliota could incorporate nucleotides opposite the gamma-HOPdG adduct, which is formed from an initial reaction of acrolein with the N(2) of guanine. We show here that Poliota incorporates a C opposite this adduct with nearly the same efficiency as it does opposite a nonadducted template G residue. The subsequent extension step, however, is performed by Polkappa, which efficiently extends from the C incorporated opposite the adduct. Based upon these observations, we suggest that an important biological role of Poliota and Polkappa is to act sequentially to carry out the efficient and accurate bypass of highly distorting minor-groove DNA adducts of the purine bases.     

The causes of hydration changes during DNA protonation

Changes of DNA hydration provoked by protonation in the way of Na+- and H+-ions exchange, and in the way of HCl addition to Na+-DNA, were analysed by IR-spectroscopy. Water is shown not to contribute essentially to the formation and stabilization of conformations arising when DNA is protonated. The differences between hydratation of DNA protonated by different ways are in the main accounted for by alteration of the quantities of Na+ and Cl- ions forming the aqueous-salt envelope of polynucleotide.     

CoMFA study of distamycin analogs binding to the minor-groove of DNA: a unified model for broad-spectrum activity

A 3D-QSAR analysis has been carried out by comparative molecular field analysis (CoMFA) on a series of distamycin analogs that bind to the DNA of drug-resistant bacterial strains MRSA, PRSP and VSEF. The structures of the molecules were derived from the X-ray structure of distamycin bound to DNA and were aligned using the Database alignment method in Sybyl. Statistically significant CoMFA models for each activity were generated. The CoMFA contours throw light on the structure activity relationship (SAR) and help to identify novel features that can be incorporated into the distamycin framework to improve the activity. Common contours have been gleaned from the three models to construct a unified model that explains the steric and electrostatic requirements for antimicrobial activity against the three resistant strains. Figure A unified CoMFA model for broad-spectrum DNA minor-groove binders     

Effect of ionic strength of a solution on the protonation of DNA molecule

The influence of the ionic strength of solution on the DNA molecule protonation was studied by means of circular dichroism (CD), spectrophotometric and potentiometric titration methods over a wide range of the supporting electrolyte concentrations [( NaCl] = 0.0005 divided by 4 M). Consideration of the obtained CD spectra shown that the acidation of the solution induces two cooperative structural transitions in the double stranded DNA molecule in the pre-denaturation pH region. Further decrease in the solution pH results in acidic melting of the DNA molecule. Analysis of the potentiometric data shows that diluted DNA solutions exhibit marked buffer capacity at pH greater than 4.2. A concept of local pH dependent on the electrostatic potential in the vicinity of the polyion was used for interpreting the obtained results. A phase diagram, which describes the polymorphic transformations of the protonated macromolecule, was constructed in terms of pHloc and -log[Na+]. Consideration of this phase diagram allows to hypothesize that: 1) in the neutral diluted DNA solution with a very low supporting electrolyte content the macromolecule exists in a polymorphic state; 2) at [NaCl] greater than or equal to 0.001 M the acid-base equilibrium in the DNA molecule is invariant in respect to the ionic strength of the solution.     

Importance of minor-groove contacts for recognition of DNA by the binding domain of Hin recombinase

Incorporation of the DNA-cleaving moiety EDTA.Fe at discrete amino acid residues along a DNA-binding protein allows the positions of these residues relative to DNA bases, and hence the organization of the folded protein, to be mapped by high-resolution gel electrophoresis. A 52-residue protein, based on the sequence-specific DNA-binding domain of Hin recombinase (139-190), with EDTA at the NH2 terminus cleaves DNA at Hin recombination sites. The cleavage data for EDTA-Hin(139-190) reveal that the NH2 terminus of Hin(139-190) is bound in the minor groove of DNA near the symmetry axis of Hin-binding sites [Sluka, J. P., Horvath, S. J., Bruist, M. F., Simon, M. I., & Dervan, P. B. (1987) Science 238, 1129]. Six proteins, varying in length from 49 to 60 residues and corresponding to the DNA-binding domain of Hin recombinase, were synthesized by solid-phase methods: Hin(142-190), Hin(141-190), Hin(140-190), Hin(139-190), Hin(135-190), and Hin(131-190) were prepared with and without EDTA at the NH2 termini in order to test the relative importance of the residues Gly139-Arg140-Pro141-Arg142, located near the minor groove, for sequence-specific recognition at five imperfectly conserved 12-base-pair binding sites. Footprinting and affinity cleaving reveal that deletion of Gly139 results in a protein with affinity and specificity similar to those of Hin(139-190) but that deletion of Gly139-Arg140 affords a protein with altered affinities and sequence specificities for the five binding sites. It appears that Arg140 in the DNA-binding domain of Hin is important for recognition of the 5'-AAA-3' sequence in the minor groove of DNA. Our results indicate modular DNA and protein interactions with two adjacent DNA sites (major and minor grooves, respectively) bound on the same face of the helix by two separate parts of the protein.     

Allosteric inhibition of zinc-finger binding in the major groove of DNA by minor-groove binding ligands

In recent years, two methods have been developed that may eventually allow the targeted regulation of a broad repertoire of genes. The engineered protein strategy involves selecting Cys(2)His(2) zinc finger proteins that will recognize specific sites in the major groove of DNA. The small molecule approach utilizes pairing rules for pyrrole-imidazole polyamides that target specific sites in the minor groove. To understand how these two methods might complement each other, we have begun exploring how polyamides and zinc fingers interact when they bind the same site on opposite grooves of DNA. Although structural comparisons show no obvious source of van der Waals collisions, we have found a significant "negative cooperativity" when the two classes of compounds are directed to the overlapping sites. Examining available crystal structures suggests that this may reflect differences in the precise DNA conformation, especially with regard to width and depth of the grooves, that is preferred for binding. These results may give new insights into the structural requirements for zinc finger and polyamide binding and may eventually lead to the development of even more powerful and flexible schemes for regulating gene expression.     

Curcumin is a potent DNA hypomethylation agent

Molecular docking of the interaction of curcumin and DNMT1 suggested that curcumin covalently blocks the catalytic thiolate of C1226 of DNMT1 to exert its inhibitory effect. This was validated by showing that curcumin inhibits the activity of M. SssI with an IC₅₀ of 30 nM, but no inhibitory activity of hexahydrocurcumin up to 100 μM. In addition, curcumin can induce global DNA hypomethylation in a leukemia cell line.     

Energetic diversity of DNA minor-groove recognition by small molecules displayed through some model ligand-DNA systems

Energetics of interactions occurring in the model ligand-DNA systems constituted from distamycin A (DST), netropsin (NET) and the oligomeric duplexes d(GCAAGTTGCGATATACG)d(CGTATATCGCAACTTGC)=D#1 and d(GCAAGTTGCGAAAAACG)d(CGTTTTTCGCAACTTGC)=D#2 was studied by spectropolarimetry, UV-absorption spectroscopy and isothermal titration calorimetry. Model analysis of the measured signals was applied to describe individual and competitive binding in terms of populations of various species in the solution. Our results reveal several unprecedented ligand-DNA binding features. DST binds to the neighboring 5'-AAGTT-3' and 5'-ATATA-3' sites of D#1 statistically in a 2:1 binding mode. By contrast, its association to D#2 appears to be a 2:1 binding event only at the DST/D#2 molar ratios between 0 and 2 while its further binding to D#2 may be considered as a step-by-step binding to the unoccupied 5'-AAAAA-3' sites resulting first in DST3D#2 and finally in DST4D#2 complex formation. Competition between DST and NET binding shows that for the most part DST displaces NET from its complexes with D#1 and D#2. In contrast to the obligatory 1:1 binding of DST to the ligand-free 5'-AAAAA-3' sites observed at DST/5'-AAAAA-3' <1 the displacement of NET bound to the 5'-AAAAA-3' sites by added DST occurs even at the smallest additions of DST in a 2:1 manner. NET can also displace DST molecules but only those bound monomerically to the 5'-AAAAA-3' sites of DST3D#2. Actually, only half of these molecules can be displaced due to the simultaneous rebinding of the displaced DST to the unreacted 5'-AAAAA-3' sites in DST3D#2. Binding of DST and NET to D#1 and D#2 is an enthalpy driven process accompanied by large unfavorable (DST), small (NET) or large favorable (NET binding to 5'-AAAAA-3') entropy contributions and negative deltaCP degrees that are reasonably close to deltaCP degrees predicted from the calculated changes in solvent-accessible surface areas that accompany complex formation. Although various modes of DST and NET binding within D#1 and D#2 are characterized by significant energetic differences they seem to be governed by the same driving forces; the hydrophobic transfer of ligand from the solution into the duplex binding site and the accompanying specific non-covalent ligand-DNA and ligand-ligand interactions occurring within the DNA minor groove.     

Replication past a trans-4-hydroxynonenal minor-groove adduct by the sequential action of human DNA polymerases iota and kappa

The X-ray crystal structure of human DNA polymerase iota (Poliota) has shown that it differs from all known Pols in its dependence upon Hoogsteen base pairing for synthesizing DNA. Hoogsteen base pairing provides an elegant mechanism for synthesizing DNA opposite minor-groove adducts that present a severe block to synthesis by replicative DNA polymerases. Germane to this problem, a variety of DNA adducts form at the N2 minor-groove position of guanine. Previously, we have shown that proficient and error-free replication through the gamma-HOPdG (gamma-hydroxy-1,N2-propano-2'-deoxyguanosine) adduct, which is formed from the reaction of acrolein with the N2 of guanine, is mediated by the sequential action of human Poliota and Polkappa, in which Poliota incorporates the nucleotide opposite the lesion site and Polkappa carries out the subsequent extension reaction. To test the general applicability of these observations to other adducts formed at the N2 position of guanine, here we examine the proficiency of human Poliota and Polkappa to synthesize past stereoisomers of trans-4-hydroxy-2-nonenal-deoxyguanosine (HNE-dG). Even though HNE- and acrolein-modified dGs share common structural features, due to their increased size and other structural differences, HNE adducts are potentially more blocking for replication than gamma-HOPdG. We show here that the sequential action of Poliota and Polkappa promotes efficient and error-free synthesis through the HNE-dG adducts, in which Poliota incorporates the nucleotide opposite the lesion site and Polkappa performs the extension reaction.     

Influence of sequence-dependent cytosine protonation and methylation on DNA triplex stability

To investigate cytosine protonation and its influence on the sequence-dependent thermal stability of DNA triplexes in detail, we have employed homo- and heteronuclear NMR experiments on specifically (15)N-labeled oligodeoxynucleotides that were designed to fold into intramolecular triple helices of the pyrimidine motif under appropriate conditions. These experiments reveal that cytosines in central positions of the triplex are significantly protonated even at neutral pH. However, semiprotonation points for individual cytosine bases as determined from pH-dependent measurements show considerable differences depending on their position. Thus, protonation is disfavored for adjacent cytosines or for cytosines at the triplex termini, resulting in a smaller contribution to the overall free energy of the triple helical system. In contrast, protonation of the base upon substitution of 5-methylcytosine for cytosine in the triplex third strand is only affected to a minor extent, and triplex stabilization by the methyl substituent is shown to primarily arise from stacking energies and/or hydrophobic effects.     

X-ray diffraction study of polymorphism of the DNA double helix at protonation

X-ray diffractograms of DNA fibers have been obtained at various degrees of protonation (alpha). At the protonation degrees preceding acid denaturation, DNA double helix undergoes polymorphic transformation. At 75% relative humidity DNA helix of 11 : 1 type protonated up to alpha = 0.3 changes to 10 : 1 type.