Affinity and kinetic modulation of polyamide–DNA interactions by N‐modification of the heterocycles

Synthetic N‐methyl imidazole and N‐pyrrole containing polyamides (PAs) that can form “stacked” dimers can be programmed to target and bind to specific DNA sequences and control gene expression. To accomplish this goal, the development of PAs with lower molecular mass which allows for the molecules to rapidly penetrate cells and localize in the nucleus, along with increased water solubility, while maintaining DNA binding sequence specificity and high binding affinity is key. To meet these challenges, six novel f‐ImPy*Im PA derivatives that contain different orthogonally positioned moieties were designed to target 5′‐ACGCGT‐3′. The synthesis and biophysical characterization of six f‐ImPy*Im were determined by CD, ΔT_M, DNase I footprinting, SPR, and ITC studies, and were compared with those of their parent compound, f‐ImPyIm. The results gave evidence for the minor groove binding and selectivity of PAs 1 and 6 for the cognate sequence 5′‐ACGCGT‐3′, and with strong affinity, K_eq = 2.8 × 10⁸ M^?1 and K_eq = 6.2 × 10⁷ M^?1, respectively. The six novel PAs presented in this study demonstrated increased water solubility, while maintaining low molecular mass, sequence specificity, and binding affinity, addressing key issues in therapeutic development. © 2013 Wiley Periodicals, Inc. Biopolymers 99: 497–507, 2013.     

Structure of a beta-alanine-linked polyamide bound to a full helical turn of purine tract DNA in the 1:1 motif

Polyamides composed of N-methylpyrrole (Py), N-methylimidazole (Im) and N-methylhydroxypyrrole (Hp) amino acids linked by beta-alanine (beta) bind the minor groove of DNA in 1:1 and 2:1 ligand to DNA stoichiometries. Although the energetics and structure of the 2:1 complex has been explored extensively, there is remarkably less understood about 1:1 recognition beyond the initial studies on netropsin and distamycin. We present here the 1:1 solution structure of ImPy-beta-Im-beta-ImPy-beta-Dp bound in a single orientation to its match site within the DNA duplex 5'-CCAAAGAGAAGCG-3'.5'-CGCTTCTCTTTGG-3' (match site in bold), as determined by 2D (1)H NMR methods. The representative ensemble of 12 conformers has no distance constraint violations greater than 0.13 A and a pairwise RMSD over the binding site of 0.80 A. Intermolecular NOEs place the polyamide deep inside the minor groove, and oriented N-C with the 3'-5' direction of the purine-rich strand. Analysis of the high-resolution structure reveals the ligand bound 1:1 completely within the minor groove for a full turn of the DNA helix. The DNA is B-form (average rise=3.3 A, twist=38 degrees ) with a narrow minor groove closing down to 3.0-4.5 A in the binding site. The ligand and DNA are aligned in register, with each polyamide NH group forming bifurcated hydrogen bonds of similar length to purine N3 and pyrimidine O2 atoms on the floor of the minor groove. Each imidazole group is hydrogen bonded via its N3 atom to its proximal guanine's exocyclic amino group. The important roles of beta-alanine and imidazole for 1:1 binding are discussed.     

Structural transition from dimeric to tetrameric i‐motif,caused by the presence of TAA at the 3′‐end of human telomeric C‐rich sequence

Widely dispersed in genomic DNA, the tandem C‐rich repetitive stretches may fold below physiological pH, into i‐motif structures, stabilized by C·C⁺ pairing. Herein, structural status of a 9‐mer stretch d(CCCTAACCC), [the truncated double repeat of human telomeric sequence], and its extended version, comprising of additional ? TAA segment at the 3′‐end, representing the complete double repeat d(CCCTAACCCTAA), has been investigated. The pH dependent monophasic UV‐melting, Gel and CD data suggested that while the truncated version adopts a bimolecular i‐motif structure, its complete double repeat (12‐mer) sequence exists in two (bimolecular and tetramolecular) forms. A model is proposed for the tetramolecular i‐motif with conventional C · C⁺ base pairs, additionally stabilized by asymmetric A · A base pairs at the ?3′ TAA flanking ends and Watson–Crick A · T hydrogen bonding between intervening bases on antiparallel strands. Expanding the known topologies of DNA i‐motifs, such atypical geometries of i‐motifs may have implications in their recognition by proteins. © 2009 Wiley Periodicals, Inc. Biopolymers 93: 150–160, 2010. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

Use of capillary electrophoresis in the study of ligand-DNA interactions.

Free solution capillary electrophoresis (FSCE) has been used to separate two non-self-complementary 12mer oligonucleotide duplexes: d(AAATTATATTAT).d(ATAA-TATAATTT) and d(GGGCCGCGCCGC).d(GCGGCGCGGCCC). Titration of mixtures of the two oligonucleotides with model intercalators (ethidium bromide andactinomycin D) and minor groove binders (netropsin, Hoechst 33258 and distamycin) has shown the suitability of FSCE as a method to study the sequence selectivity of DNA binding agents. Binding data have shown cooperativity of binding for netropsin and Hoechst 33258 and have provided ligand:DNA binding ratios for all five compounds. Cooperativity of netropsin binding to a 12mer with two potential sites has been demonstrated for the first time. Ligands binding in the minor groove caused changes in migration time and peak shape which were significantly different from those caused by intercalators.     

Distamycin-induced inhibition of formation of a nucleoprotein complex between the terminase small subunit G1P and the non-encapsidated end (pacL site) of Bacillus subtilis bacteriophage SPP1.

The small subunit of the Bacillus subtilis bacteriophage SPP1 terminase (G1P) forms a sequence-specific nucleoprotein complex with the SPP1 non-encapsidated end (pacL site) during initiation of DNA encapsidation. Gel mobility shift assay was used to study the G1P-pacL interaction. Distamycin, a minor groove binder that induces local distortion of the DNA, inhibits G1P-pacL complex formation. The competition of G1P with distamycin for DNA binding at the pacL site is independent of the order of addition of the reactants. Other minor groove binders, such as spermine or Hoechst 33258, which do not distort DNA, failed to compete with G1P for pacL DNA binding. Cationic metals, which generate a repertoire of DNA structures different from that caused by the minor groove binders, can partially reverse the distamycin-induced inhibition of G1P binding to pacL DNA. The major groove binder methyl green, which does not distort sequence-directed bending of pacL DNA, competes with G1P for binding at the pacL site. Our data suggest that the natural sequence-directed bend that exists within the pacL site is the architectural element that facilitates assembly of a nucleoprotein complex and hence initiation of DNA encapsidation by bacteriophage SPP1.     

Studies of the Activity of Peroxidase‐Like DNAzyme by Modifying 3′‐ or 5′‐End of Aptamers

In the presence of hemin and under appropriate conditions, some modalities of G‐quadruplexes can form a peroxidase‐like DNAzyme that has been widely used in biology. Structure? function studies on the DNAzyme revealed that its catalytic ability may be dependent on the unimolecular parallel G‐quadruplex. In this report, we present the preliminary investigation on the relationship between the structure and function of DNAzymes through a terminal oligo modification in G‐quadruplex sequences by adding different lengths of oligo‐dT to the 3′‐ or 5′‐end of the aptamers. The results suggested that adding dT_n to the 5′‐end of the DNA sequence of the enzyme improved the ability of hemin to bind with DNA, but the addition of dT_n to the 3′‐end decreased the binding ability of hemin for DNA. The increased stability of the assembled DNAzyme would lead to more favorable binding between the enzyme and substrate (H₂O₂), facilitating higher peroxidase activity; on the contrary, with lower stability of the DNAzyme complex, we observed reduced peroxidase activity.     

A polarized-light spectroscopy study of interactions of a hairpin polyamide with DNA

We here study the interactions of a polyamide with large DNA, and compare to those of minor groove binder distamycin (DST), including high ligand/DNA binding ratios. Specific as well as nonspecific binding is probed using polarized-light spectroscopy combined with singular value decomposition analysis. Circular and linear dichroism data confirm binding geometries consistent with minor groove binding for both of the ligands. Interestingly, at high and intermediate ligand/DNA ratios the polyamide exhibits no significant sequence discrimination between mixed-sequence (calf thymus) and AT DNA as compared to DST. Each ligand is concluded to exhibit two different binding modes depending upon ligand/DNA ratio and nucleo-base sequence. At high binding ratios, distinct differences between the ligands are observed: circular dichroism spectra exciton effects provide evidence of bimolecular interactions of the polyamide when bound to AT-DNA, whereas no effects are seen with DST or mixed-sequence DNA. Also linear dichroism indicates that a change in binding geometry occurs at high polyamide/AT ratios, and that the effect occurs only with polyamide in contrast to DST. Since the effect is insignificant with DST, or with calf thymus DNA, it is concluded that it relates to the sizes of the ligands and the minor grooves, becoming critical in the limit of crowding.     

Alternative heterocycles for DNA recognition: a 3-pyrazole/pyrrole pair specifies for G.C base pairs

Synthetic ligands comprising three aromatic amino acids, pyrrole (Py), imidazole (Im), and hydroxypyrrole (Hp), specifically recognize predetermined sequences as side-by-side pairs in the minor groove of DNA. To expand the repertoire of aromatic rings that may be utilized for minor groove recognition, three five-membered heterocyclic rings, 3-pyrazolecarboxylic acid (3-Pz), 4-pyrazolecarboxylic acid (4-Pz), and furan-2-carboxylic acid (Fr), were examined at the N-terminus of eight-ring hairpin polyamide ligands. The DNA binding properties of 3-Pz, 4-Pz, and Fr each paired with Py were studied by quantitative DNase I footprinting titrations on a 283 bp DNA restriction fragment containing four 6-bp binding sites 5'-ATNCCTAA-3' (N = G, C, A, or T; 6-bp polyamide binding site is underlined). The pair 3-Pz/Py has increased binding affinity and sequence specificity for G.C bp compared with Im/Py.     

DNA-sequence specific recognition by a thiazole analogue of netropsin: a comparative footprinting study.

Four different footprinting techniques have been used to probe the DNA sequence selectivity of Thia-Net, a bis-cationic analogue of the minor groove binder netropsin in which the N-methylpyrrole moieties are replaced by thiazole groups. In Thia-Net the ring nitrogen atoms are directed into the minor groove where they could accept hydrogen bonds from the exocyclic 2-amino group of guanine. Three nucleases (DNAase I, DNAase II, and micrococcal nuclease) were employed to detect binding sites on the 160bp tyr T fragment obtained from plasmid pKM delta-98, and further experiments were performed with 117mer and 253mer fragments cut out of the plasmid pBS. MPE.Fe(II) was used to footprint binding sites on an EcoRI/HindIII fragment from pBR322. Thia-Net binds to sites in the minor groove containing 4 or 5 base pairs which are predominantly composed of alternating A and T residues, but with significant acceptance of intrusive GC base pairs. Unlike the parent antibiotic netropsin, Thia-Net discriminates against homooligomeric runs of A and T. The evident preference of Thia-Net for AT-rich sites, despite its containing thiazole nitrogens capable of accepting GC sites by hydrogen bonding, supports the view that the biscationic nature of the ligand imposes a bias due to the electrostatic potential differences in the receptor which favour the ligand reading alternating AT sequences.     

Enzyme‐Free Ligation of 5′‐Phosphorylated Oligodeoxynucleotides in a DNA Nanostructure

Multicomponent reactions are difficult synthetic transformations. For DNA, there is a special opportunity to align multiple strands in a folded nanostructure, so that they are preorganized to give a specific sequence. Multistrand reactions in DNA origami structures have previously been performed using photochemical crosslinking, 1,3‐diploar cycloadditions or phosphoramidate‐forming reactions. Here we report carbodiimide‐driven phosphodiester formation in a small origami sheet that produces DNA strands up to 600 nucleotides in length in a single step. The method uses otherwise unmodified oligodeoxynucleotides with a 5′‐terminal phosphate as starting materials. Compared to an enzymatic multistrand ligation involving linear duplexes, the carbodiimide‐driven ligation gave fewer side products, as detected by gel electrophoresis. The full‐length 600mer product was successfully amplified by polymerase chain reaction.     

Oligonucleotide—Minor Groove Binder 1:2 Conjugates: Side by Side Parallel Minor Groove Binder Motif in Stabilization of DNA Duplex

Synthetic polycarboxamides consisting of N‐methylpyrrole (Py), N‐methylimidazole (Im), N‐methyl‐3‐hydroxypyrrole (Hp) and β‐alanine (β) show strong and sequence‐specific interaction with the DNA minor groove when they form hairpin structures with side‐by‐side antiparallel motifs. In the present paper, new conjugates containing two ligands linked to the same terminal phosphate of DNA strand were constructed. The paper describes optimized synthesis and properties of oligonucleotide‐linked polyamide strands that insert into the minor groove of a duplex in a parallel or antiparallel orientation. Strong stabilization of DNA duplexes by two attached minor groove ligands is demonstrated by the thermal denaturation method. The unmodified duplex 5′‐CGTTTATTp‐3′/5′‐AATAAACG‐3′ melts at 20°C. When one tetra(Py) residue was attached to the first strand of this duplex, denaturation temperature was increased to 46°C; attachment of the second tetra(Py) in a parallel orientation resulted in denaturation temperature of 60°C. It is even higher than in case of “classic” octapyrrole hairpin ligand (Tm = 58°C). Sequence‐specific character of stabilization by two conjugated ligands was demonstrated for G:C‐containing oligonucleotides attached to tetracarboxamide and octacarboxamide ligands constructed from Py, Im and β units according to established recognition rules (ΔTm = 20°C). The two‐strand parallel minor groove binder constructions attached to addressing oligonucleotides could be considered as site‐specific ligands recognizing single‐ and double‐stranded DNA similarly to already described hairpin MGB structures with antiparallel orientation of carboxamide units.     

Probing the interaction of distamycin A with S100β: the “unexpected” ability of S100β to bind to DNA‐binding ligands

DNA‐minor‐groove‐binding ligands are potent antineoplastic molecules. The antibiotic distamycin A is the prototype of one class of these DNA‐interfering molecules that have been largely used in vitro. The affinity of distamycin A for DNA is well known, and the structural details of the complexes with some B‐DNA and G‐quadruplex‐forming DNA sequences have been already elucidated. Here, we show that distamycin A binds S100β, a protein involved in the regulation of several cellular processes. The reported affinity of distamycin A for the calcium(II)‐loaded S100β reinforces the idea that some biological activities of the DNA‐minor‐groove‐binding ligands arise from the binding to cellular proteins. Copyright © 2015 John Wiley & Sons, Ltd.     

Diverse modes of 5′‐[4‐(aminoiminomethyl)phenyl]‐[2,2′‐bifuran]‐5‐carboximidamide (DB832) interaction with multi‐stranded DNA structures

The modes of binding of 5′‐[4‐(aminoiminomethyl)phenyl]‐[2,2′‐Bifuran]‐5‐carboximidamide (DB832) to multi‐stranded DNAs: human telomere quadruplex, monomolecular R‐triplex, pyr/pur/pyr triplex consisting of 12 T*(T·A) triplets, and DNA double helical hairpin were studied. The optical adsorption of the ligand was used for monitoring the binding and for determination of the association constants and the numbers of binding sites. CD spectra of DB832 complexes with the oligonucleotides and the data on the energy transfer from DNA bases to the bound DB832 assisted in elucidating the binding modes. The affinity of DB832 to the studied multi‐stranded DNAs was found to be greater (K_ass ≈ 10⁷M^?1) than to the duplex DNA (K_ass ≈ 2 × 10⁵M^?1). A considerable stabilizing effect of DB832 binding on R‐triplex conformation was detected. The nature of the ligand tight binding differed for the studied multi‐stranded DNA depending on their specific conformational features: recombination‐type R‐triplex demonstrated the highest affinity for DB832 groove binding, while pyr/pur/pyr TTA triplex favored DB832 intercalation at the end stacking contacts and the human telomere quadruplex d[AG₃(T₂AG₃)₃] accommodated the ligand in a capping mode. Additionally, the pyr/pur/pyr TTA triplex and d[AG₃(T₂AG₃)₃] quadruplex bound DB832 into their grooves, though with a markedly lesser affinity. DB832 may be useful for discrimination of the multi‐sranded DNA conformations and for R‐triplex stabilization. © 2009 Wiley Periodicals, Inc. Biopolymers 93: 8–20, 2010. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

DNA binding properties of minor groove binders and their influence on the topoisomerase II cleavage reaction

We present titrations of the human δβ-globin gene region with DNA minor groove binders netropsin, bisnetropsin, distamycin, chromomycin and four bis-quaternary ammonium compounds in the presence of calf thymus topoisomerase II and DNase I. With increasing ligand concentration, stimulation and inhibition of enzyme activity were detected and quantitatively evaluated. Additionally we show a second type of stimulation, the appearance of strong new topoisomerase II cleavage sites at high ligand concentrations. The specific binding sites of the minor groove binders of the DNA sequence and their microscopic binding constants were determined from DNase I footprints. A binding mechanism for minor groove binders is proposed in order to explain these results especially when ligand concentration is increased. © 1998 John Wiley & Sons, Ltd.     

Sequence specific and high affinity recognition of 5'-ACGCGT-3' by rationally designed pyrrole-imidazole H-pin polyamides: thermodynamic and structural studies

Imidazole (Im) and Pyrrole (Py)-containing polyamides that can form stacked dimers can be programmed to target specific sequences in the minor groove of DNA and control gene expression. Even though various designs of polyamides have been thoroughly investigated for DNA sequence recognition, the use of H-pin polyamides (covalently cross-linked polyamides) has not received as much attention. Therefore, experiments were designed to systematically investigate the DNA recognition properties of two symmetrical H-pin polyamides composed of PyImPyIm (5) or f-ImPyIm (3e, f=formamido) tethered with an ethylene glycol linker. These compounds were created to recognize the cognate 5'-ACGCGT-3' through an overlapped and staggered binding motif, respectively. Results from DNaseI footprinting, thermal denaturation, circular dichroism, surface plasmon resonance and isothermal titration microcalorimetry studies demonstrated that both H-pin polyamides bound with higher affinity than their respective monomers. The binding affinity of formamido-containing H-pin 3e was more than a hundred times greater than that for the tetraamide H-pin 5, demonstrating the importance of having a formamido group and the staggered motif in enhancing affinity. However, compared to H-pin 3e, tetraamide H-pin 5 demonstrated superior binding preference for the cognate sequence over its non-cognates, ACCGGT and AAATTT. Data from SPR experiments yielded binding constants of 1.6x10(8)M(-1) and 2.0x10(10)M(-1) for PyImPyIm H-pin 5 and f-ImPyIm H-pin 3e, respectively. Both H-pins bound with significantly higher affinity (ca. 100-fold) than their corresponding unlinked PyImPyIm 4 and f-ImPyIm 2 counterparts. ITC analyses revealed modest enthalpies of reactions at 298 K (DeltaH of -3.3 and -1.0 kcal mol(-1) for 5 and 3e, respectively), indicating these were entropic-driven interactions. The heat capacities (DeltaC(p)) were determined to be -116 and -499 cal mol(-1)K(-1), respectively. These results are in general agreement with DeltaC(p) values determined from changes in the solvent accessible surface areas using complexes of the H-pins bound to (5'-CCACGCGTGG)(2). According to the models, the H-pins fit snugly in the minor groove and the linker comfortably holds both polyamide portions in place, with the oxygen atoms pointing into the solvent. In summary, the H-pin polyamide provides an important molecular design motif for the discovery of future generations of programmable small molecules capable of binding to target DNA sequences with high affinity and selectivity.     

Flexible docking of DNA fragments and actinocin derivatives

We have applied molecular docking methods to systems containing nucleic acids as targets and biologically active substances as ligands. The complexes of DNA fragments and actinocin derivatives with different lengths of aminoalkyl side chains were obtained by molecular docking. It was observed that actinocin derivatives could form energetically favourable complexes with DNA both as intercalators and minor groove binders. It was shown that small changes in the binding energy (～1?kcal/mol) could result in complexes with substantially different structure. The complexes of actinocin derivatives and DNA fragments were stabilized by hydrogen bonding upon intercalation and minor groove binding. It was found that the change of solvent-accessible surface area upon binding of the actinocin derivative to DNA linear increased with the growth of methylene groups' number in ligand side chains. The solvation energy change upon binding of actinocin derivatives to DNA calculated by the WSAS method was favourable in the case of small uncharged ligands and unfavourable for positively charged ligands.     

Distamycin-induced inhibition of homeodomain-DNA complexes.

The mobility shift assay was used to study the competition of the minor groove binder distamycin A with either an Antennapedia homeodomain (Antp HD) peptide or derivatives of a fushi tarazu homeodomain (ftz HD) peptide for their AT-rich DNA binding site. The results show that distamycin and the homeodomain peptides compete under the conditions: (i) preincubation of DNA with distamycin and subsequent addition of HD peptide; (ii) simultaneous incubation of DNA with distamycin and HD peptide; and (iii) preincubation of DNA with HD peptide and subsequent addition of distamycin. There is also competition when using a peptide which lacks the N-terminal arm of ftz HD that is involved in contacts in the minor groove. It is proposed that the protein's binding affinity is diminished by distamycin-induced conformational changes of the DNA. The feasibility of the propagation of conformational changes upon binding in the minor groove is also shown for the inhibition of restriction endonucleases differing in the AT content of their recognition site and of their flanking DNA sequences. Thus, it is demonstrated that minor groove binders can compete with the binding of proteins in the major groove, providing an experimental indication for the influence of biological activities exerted by DNA ligands binding in the minor groove.     

Conformational features of benzo‐homologated yDNA duplexes by molecular dynamics simulation

yDNA is a base‐modified nucleic acid duplex containing size‐expanded nucleobases. Base‐modified nucleic acids could expand the genetic alphabet and thereby enhance the functional potential of DNA. Unrestrained 100 ns MD simulations were performed in explicit solvent on the yDNA NMR sequence [5′(yA T yA yA T yA T T yA T)₂] and two modeled yDNA duplexes, [5′(yC yC G yC yC G G yC G G)₂] and [(yT5′ G yT A yC yG C yA yG T3′)?(yA5′ C T C yG C G yT A yC A3′)]. The force field parameters for the yDNA bases were derived in consistent with the well‐established AMBER force field. Our results show that DNA backbone can withstand the stretched size of the bases retaining the Watson‐Crick base pairing in the duplexes. The duplexes retained their double helical structure throughout the simulations accommodating the strain due to expanded bases in the backbone torsion angles, sugar pucker and helical parameters. The effect of the benzo‐expansion is clearly reflected in the extended C1′‐C1′ distances and enlarged groove widths. The size expanded base modification leads to reduction in base pair twist resulting in larger overlapping area between the stacked bases, enhancing inter and intra strand stacking interactions in yDNA in comparison with BDNA. This geometry could favour enhanced interactions with the groove binders and DNA binding proteins., 2016. © 2015 Wiley Periodicals, Inc. Biopolymers 105: 55–64, 2016