Sequence‐Specific DNA Alkylation by Tandem Py–Im Polyamide Conjugates

Tandem N‐methylpyrrole? N‐methylimidazole (Py? Im) polyamides with good sequence‐specific DNA‐alkylating activities have been designed and synthesized. Three alkylating tandem Py? Im polyamides with different linkers, which each contained the same moiety for the recognition of a 10 bp DNA sequence, were evaluated for their reactivity and selectivity by DNA alkylation, using high‐resolution denaturing gel electrophoresis. All three conjugates displayed high reactivities for the target sequence. In particular, polyamide 1 , which contained a β‐alanine linker, displayed the most‐selective sequence‐specific alkylation towards the target 10 bp DNA sequence. The tandem Py? Im polyamide conjugates displayed greater sequence‐specific DNA alkylation than conventional hairpin Py? Im polyamide conjugates ( 4 and 5 ). For further research, the design of tandem Py? Im polyamide conjugates could play an important role in targeting specific gene sequences.     

Cysteine cyclic pyrrole-imidazole polyamide for sequence-specific recognition in the DNA minor groove

Pyrrole-imidazole (PI) polyamides are small DNA-binding molecules that can recognize predetermined DNA sequences with high affinity and specificity. Hairpin PI polyamides have been studied intensively; however, cyclic PI polyamides have received less attention, mainly because of difficulties with their synthesis. Here, we describe a novel cyclization method for producing PI polyamides using cysteine and a chloroacetyl residue. The cyclization reaction is complete within 1 h and has a high conversion efficiency. The method can be used to produce long cyclic PI polyamides that can recognize 7 bp DNA sequences. A cyclic PI polyamide containing two β-alanine molecules had higher affinity and specificity than the corresponding hairpin PI polyamide, demonstrating that the cyclic PI polyamides can be used as a new type of DNA-binding molecule.     

Mapping Polyamide–DNA Interactions in Human Cells Reveals a New Design Strategy for Effective Targeting of Genomic Sites

Targeting the genome with sequence‐specific synthetic molecules is a major goal at the interface of chemistry, biology, and personalized medicine. Pyrrole/imidazole‐based polyamides can be rationally designed to target specific DNA sequences with exquisite precision in vitro; yet, the biological outcomes are often difficult to interpret using current models of binding energetics. To directly identify the binding sites of polyamides across the genome, we designed, synthesized, and tested polyamide derivatives that enabled covalent crosslinking and localization of polyamide–DNA interaction sites in live human cells. Bioinformatic analysis of the data reveals that clustered binding sites, spanning a broad range of affinities, best predict occupancy in cells. In contrast to the prevailing paradigm of targeting single high‐affinity sites, our results point to a new design principle to deploy polyamides and perhaps other synthetic molecules to effectively target desired genomic sites in vivo.     

Determination of Allosteric Effects and Interstrand Bidentate Interactions in DNA‐Peptide Molecular Recognition

To study DNA allostery, quantitative DNase I footprinting studies were carried out on a newly designed peptide His‐Hyp‐Lys‐Lys‐(Py)₄‐Lys‐Lys‐NH₂ (HypKK‐10) containing the XHypKK (Hyp = hydroxyproline) and polyamide motifs. The interconnection of DNA footprints of peptides HypKK‐10 and the parent peptide PyPro‐12 supports the proposal that interaction network cooperativity is preferred in DNA‐peptide interactions between multiple recognition sites. A simple method of determining interstrand bidentate interactions between the peptide moieties and DNA bases is introduced. It is envisaged that interstrand bidentate interactions also participate in the relay of conformational changes to recognition sites on the complementary strands. Circular dichroism studies of the titration of peptide HypKK‐10 with an oligonucleotide duplex indicate that this peptide binds in a dimeric fashion to DNA in the minor groove. This work may prompt the design of new DNA binding ligands for the study of DNA‐peptide allosteric interactions and DNA interaction network.     

Electrospray ionization mass spectrometric analysis of noncovalent complexes between DNA and polyamides containing N-methylpyrrole and N-methylimidazole

Electrospray ionization mass spectrometry was utilized to investigate the noncovalent complexes between novel polyamides and DNA containing the TCCT sequence. We analyzed the noncovalent binding of the polyamides with the DNA and assessed their relative affinities and stoichiometry. The results confirm that hairpin polyamides have higher binding affinities than three-ring polyamides. The hairpin polyamide (PyPyPyPygammaPyImImPybetaDp) has the highest affinity, and the beta-linked polyamide (PyPyPybetaImImImbetaDp) shows a dominant 1:2 binding stoichiometry. Two groups of competition experiments were undertaken to compare the binding affinities of the duplex DNA with different polyamides directly. The affinity scale thus obtained for the group-1 polyamides is PyPyPyPygammaPyImImPybetaDp > PyPyPybetaImImImbetaDp approximately PyPyPygammaImImImbetaDp > PyPyPybetaDp > PyImImbetaDp approximately ImImPybetaDp, and the order for the group-2 polyamides is PyPyPygammaImImImbetaDp > PyPyPygammaImImImbetaOEt > PyPyPygammaImImImbetaCOOH.     

Tandem trimer pyrrole–imidazole polyamide probes targeting 18 base pairs in human telomere sequences

The binding of molecules to specific DNA sequences is important for imaging genome DNA and for studying gene expression. Increasing the number of base pairs targeted by these molecules would provide greater specificity. N-Methylpyrrole–N-methylimidazole (Py–Im) polyamides are one type of such molecules and can bind to the minor groove of DNA in a sequence-specific manner without causing denaturation of DNA. Our recent work has demonstrated that tandem hairpin Py–Im polyamides conjugated with a fluorescent dye can be synthesized easily and can serve as new probes for studying human telomeres under mild conditions. Herein, to improve their selectivities to telomeres by targeting longer sequences, we designed and synthesized a fluorescent tandem trimer Py–Im polyamide probe, comprising three hairpins and two connecting regions (hinges). The new motif bound to 18 bp dsDNA in human telomeric repeats (TTAGGG)_n, the longest sequence for specific binding reported for Py–Im polyamides. We compared the binding affinities and the abilities to discriminate mismatch, the UV-visible absorption and fluorescence spectra, and telomere staining in human cells between the tandem trimer and a previously developed tandem hairpin. We found that the tandem trimer Py–Im polyamide probe has higher ability to recognize telomeric repeats and stains telomeres in chemically fixed cells with lower background signal.     

Influence of a terminal formamido group on the sequence recognition of DNA by polyamides

Pyrrole (Py)-imidazole (Im)-containing polyamides bind in the minor groove of DNA and can recognize specific sequences through a stacked antiparallel dimer. It has been proposed that there are two different low energy ways to form the stacked dimer and that these are sensitive to the presence of a terminal formamido group: (i) a fully overlapped stacking mode in which the N-terminal heterocycles of the dimer stack on the amide groups between the two heterocycles at the C-terminal and (ii) a staggered stacking mode in which the N-terminal heterocycles are shifted by approximately one unit in the C-terminal direction (Structure 1997, 5, 1033-1046). Two different DNA sequences will be recognized by the same polyamide stacked in these two different modes. Despite the importance of polyamides as sequence specific DNA recognition agents, these stacking possibilities have not been systematically explored. As part of a program to develop agents that can recognize mismatched base pairs in DNA, a set of four polyamide trimers with and without terminal formamido groups was synthesized, and their interactions with predicted DNA recognition sequences in the two different stacking modes were evaluated. Experimental difficulties in monitoring DNA complex formation with polyamides were overcome by using surface plasmon resonance (SPR) detection of the binding to immobilized DNA hairpin duplexes. Both equilibrium and kinetic results from SPR show that a terminal formamido group has a pronounced effect on the affinity, sequence specificity, and rates of DNA-dimer complex formation. The formamido polyamides bind preferentially in the staggered stacking mode, while the unsubstituted analogues bind in the overlapped mode. Affinities for cognate DNA sequences increase by a factor of around 100 when a terminal formamido is added to a polyamide, and the preferred sequences recognized are also different. Both the association and the dissociation rates are slower for the formamido derivatives, but the effect is larger for the dissociation kinetics. The formamido group thus strongly affects the interaction of polyamides with DNA and changes the preferred DNA sequences that are recognized by a specific polyamide stacked dimer.     

Evaluation of binding selectivity of a polyamide probe to single base-pair different dna in A·T-rich region by electrospray ionization mass spectrometry

In this study, electrospray ionization mass spectrometry (ESI-MS) was used for the evaluation of the binding selectivity of a polyamide probe to single-base pair different DNA in an A.T-rich region. In this procedure, DeltaIr(dsn) was introduced as a parameter to compare the binding affinities of the polyamides with the duplex DNA. The results show that ESI-MS is a very useful tool for analysis of binding selectivity of a polyamide probe to single-base pair different DNA.     

Sequence-specific alkylation by Y-shaped and tandem hairpin pyrrole-imidazole polyamides

To extend the target DNA sequence length of the hairpin pyrrole-imidazole (Py-Im) polyamide 1, we designed and synthesized Y-shaped and tandem hairpin Py-Im polyamides 2 and 3, which possess 1-(chloromethyl)-5-hydroxy-1,2-dihydro-3H-benz[e]indole (seco-CBI) as DNA-alkylating moieties. High-resolution denaturing polyacrylamide gel electrophoresis by using 5'-Texas-Red-labeled 465 base pair (bp) DNA fragments revealed that conjugates 2 and 3 alkylated the adenine of the target DNA sequences at nanomolar concentrations. Conjugate 2 alkylated adenine N3 at the 3' end of two 8 bp match sequences, 5'-AATAACCA-3' (site A) and 5'-AAATTCCA-3' (site C), while conjugate 3 recognized one 10 bp match sequence, 5'-AGAATAACCA-3' (site A) in the 465 bp DNA fragments. These results demonstrate that seco-CBI conjugates of Y-shaped and tandem hairpin polyamides have extended their target alkylation sequences.     

Structural and Kinetic Profiling of Allosteric Modulation of Duplex DNA Induced by DNA-Binding Polyamide Analogues

A combined structural and quantitative biophysical profile of the DNA binding affinity, kinetics and sequence-selectivity of hairpin polyamide analogues is described. DNA duplexes containing either target polyamide binding sites or mismatch sequences are immobilized on a microelectrode surface. Quantitation of the DNA binding profile of polyamides containing N-terminal 1-alkylimidazole (Im) units exhibit picomolar binding affinities for their target sequences, whereas 5-alkylthiazole (Nt) units are an order of magnitude lower (low nanomolar). Comparative NMR structural analyses of the polyamide series shows that the steric bulk distal to the DNA-binding face of the hairpin iPr-Nt polyamide plays an influential role in the allosteric modulation of the overall DNA duplex structure. This combined kinetic and structural study provides a foundation to develop next-generation hairpin designs where the DNA-binding profile of polyamides is reconciled with their physicochemical properties.     

Investigation of non-covalent complexes of HIV-1 promoter DNA and polyamides containing N-methylpyrrole by electrospray ionization mass spectrometry

Eight novel polyamides containing N-methylpyrrole were designed to target the sequence (5'-CTGCATATAAGCAG-3'/5'-CTGCTTATATGCAG-3') of the TATA box element of the HIV-1 promoter DNA. The non-covalent complexes of the promoter DNA and the polyamides were investigated by electrospray ionization (ESI) mass spectrometry, which provided strong evidence for the binding of the novel polyamides to the sequence of the TATA box element. It also revealed that polyamide 2 (PyPyPyPybetaDp), a potent binder of HIV-1 promoter DNA and a lead molecule for the design of new anti-HIV-1 drugs, had the highest binding affinity with the TATA box element DNA among these polyamides by examining the stoichiometry and the selectivity.     

Centromeric Alpha‐Satellite DNA Adopts Dimeric i‐Motif Structures Capped by AT Hoogsteen Base Pairs

Human centromeric alpha‐satellite DNA is composed of tandem arrays of two types of 171 bp monomers; type A and type B. The differences between these types are concentrated in a 17 bp region of the monomer called the A/B box. Here, we have determined the solution structure of the C‐rich strand of the two main variants of the human alpha‐satellite A box. We show that, under acidic conditions, the C‐rich strands of two A boxes self‐recognize and form a head‐to‐tail dimeric i‐motif stabilized by four intercalated hemi‐protonated C:C⁺ base pairs. Interestingly, the stack of C:C⁺ base pairs is capped by T:T and Hoogsteen A:T base pairs. The two main variants of the A box adopt a similar three‐dimensional structure, although the residues involved in the formation of the i‐motif core are different in each case. Together with previous studies showing that the B box (known as the CENP‐B box) also forms dimeric i‐motif structures, our finding of this non‐canonical structure in the A box shows that centromeric alpha satellites in all human chromosomes are able to form i‐motifs, which consequently raises the possibility that these structures may play a role in the structural organization of the centromere.     

Sequence‐Specific DNA Alkylation Targeting for Kras Codon 13 Mutation by Pyrrole–Imidazole Polyamide seco‐CBI Conjugates

Hairpin N‐methylpyrrole‐N‐methylimidazole polyamide seco‐CBI conjugates 2 – 6 were designed for synthesis by Fmoc solid‐phase synthesis, and their DNA‐alkylating activities against the Kras codon 13 mutation were compared by high‐resolution denaturing gel electrophoresis with 225 base pair (bp) DNA fragments. Conjugate 5 had high reactivity towards the Kras codon 13 mutation site, with alkylation occurring at the A of the sequence 5′‐ACGTCACC A ‐3′ (site 2), including minor 1 bp‐mismatch alkylation against wild type 5′‐ACG C CACC A ‐3′ (site 3). Conjugate 6 , which differs from conjugate 5 by exchanging one Py unit with a β unit, showed high selectivity but only weakly alkylated the A of 5′‐ACGTCACC A ‐3′ (site 2). The hairpin polyamide seco‐CBI conjugate 5 thus alkylates according to Dervan′s pairing rule with the pairing recognition which β/β pair targets T–A and A–T pairs. SPR and a computer‐minimized model suggest that 5 binds to the target sequence with high affinity in a hairpin conformation, allowing for efficient DNA alkylation.     

Discrimination of A/T sequences in the minor groove of DNA within a cyclic polyamide motif

Eight-ring cyclic polyamides containing pyrrole (Py), imidazole (Im), and hydroxypyrrole (Hp) aromatic amino acids recognize predetermined six base pair sites in the minor groove of DNA. Two four-ring polyamide subunits linked by (R)-2,4-diaminobutyric acid [(R)H2Ngamma] residue form hairpin polyamide structures with enhanced DNA binding properties. In hairpin polyamides, substitution of Hp/Py for Py/Py pairs enhances selectivity for T. A base pairs but compromises binding affinity for specific sequences. In an effort to enhance the binding properties of polyamides containing Hp/Py pairings, four eight ring cyclic polyamides were synthesized and analyzed on a DNA restriction fragment containing three 6-bp sites 5'-tAGNNCTt-3', where NN = AA, TA, or AT. Quantitative footprint titration experiments demonstrate that contiguous placement of Hp/Py pairs in cyclo-(gamma-ImPyPyPy-(R)H2Ngamma-ImHpHpPy-) (1) provides a 20-fold increase in affinity for the 5'-tAGAACTt-3' site (Ka = 7.5 x 10(7)M(-1)) relative to ImPyPyPy-(R)H2Ngamma-ImHpHpPy-C3-OH (2). A cyclic polyamide of sequence composition cyclo-(gamma-ImHpPyPy-(R)H2Ngamma-ImHpPyPy-) (3) binds a 5'-tAGTACTt-3' site with an equilibrium association constant KA= 3.2 x 10(9)M(-1), representing a fivefold increase relative to the hairpin analogue ImHpPyPy-(R)H2Ngamma-ImHpPyPy-C3-OH (4). Arrangement of Hp/Py pairs in a 3'-stagger regulates specificity of cyclo-(gamma-ImPyHpPy-(R)H2Ngamma-ImPyHpPy-) (5) for the 5'-tAGATCTt-3' site (Ka = 7.5 x 10(7)M(-1)) threefold increase in affinity relative to the hairpin analogue ImPyHpPy-(R)H2Ngamma-ImPyHpPy-C3-OH (6), respectively. This study identifies cyclic polyamides as a viable motif for restoring recognition properties of polyamides containing Hp/Py pairs.     

Extending the language of DNA molecular recognition by polyamides: unexpected influence of imidazole and pyrrole arrangement on binding affinity and specificity

Pyrrole (Py) and imidazole (Im) polyamides can be designed to target specific DNA sequences. The effect that the pyrrole and imidazole arrangement, plus DNA sequence, have on sequence specificity and binding affinity has been investigated using DNA melting (DeltaT(M)), circular dichroism (CD), and surface plasmon resonance (SPR) studies. SPR results obtained from a complete set of triheterocyclic polyamides show a dramatic difference in the affinity of f-ImPyIm for its cognate DNA (K(eq) = 1.9 x 10(8) M(-1)) and f-PyPyIm for its cognate DNA (K(eq) = 5.9 x 10(5) M(-1)), which could not have been anticipated prior to characterization of these compounds. Moreover, f-ImPyIm has a 10-fold greater affinity for CGCG than distamycin A has for its cognate, AATT. To understand this difference, the triamide dimers are divided into two structural groupings: central and terminal pairings. The four possible central pairings show decreasing selectivity and affinity for their respective cognate sequences: -ImPy > -PyPy- > -PyIm- approximately -ImIm-. These results extend the language of current design motifs for polyamide sequence recognition to include the use of "words" for recognizing two adjacent base pairs, rather than "letters" for binding to single base pairs. Thus, polyamides designed to target Watson-Crick base pairs should utilize the strength of -ImPy- and -PyPy- central pairings. The f/Im and f/Py terminal groups yielded no advantage for their respective C/G or T/A base pairs. The exception is with the -ImPy- central pairing, for which f/Im has a 10-fold greater affinity for C/G than f/Py has for T/A.     

Nucleotide‐Independent Copper(II)‐Based Distance Measurements in DNA by Pulsed ESR Spectroscopy

A site‐specific Cu²⁺ binding motif within a DNA duplex for distance measurements by ESR spectroscopy is reported. This motif utilizes a commercially available 2,2′‐dipicolylamine (DPA) phosphormadite easily incorporated into any DNA oligonucleotide during initial DNA synthesis. The method only requires the simple post‐synthetic addition of Cu²⁺ without the need for further chemical modification. Notably, the label is positioned within the DNA duplex, as opposed to outside the helical perimeter, for an accurate measurement of duplex distance. A distance of 2.7 nm was measured on a doubly Cu²⁺‐labeled DNA sequence, which is in exact agreement with the expected distance from both DNA modeling and molecular dynamic simulations. This result suggests that with this labeling strategy the ESR measured distance directly reports on backbone DNA distance, without the need for further modeling. Furthermore, the labeling strategy is structure‐ and nucleotide‐independent.     

Additional Base‐Pair Formation in DNA Duplexes by a Double‐Headed Nucleotide

We have designed and synthesised a double‐headed nucleotide that presents two nucleobases in the interior of a dsDNA duplex. This nucleotide recognises and forms Watson–Crick base pairs with two complementary adenosines in a Watson–Crick framework. Furthermore, with judicious positioning in complementary strands, the nucleotide recognises itself through the formation of a T:T base pair. Thus, two novel nucleic acid motifs can be defined by using our double‐headed nucleotide. Both motifs were characterised by UV melting experiments, CD and NMR spectroscopy and molecular dynamics simulations. Both motifs leave the thermostability of the native dsDNA duplex largely unaltered. Molecular dynamics calculations showed that the double‐headed nucleotides are accommodated in the dsDNA by entirely local perturbations and that the modified duplexes retain an overall B‐type geometry with the dsDNA unwound by around 25 or 60°, respectively, in each of the modified motifs. Both motifs can be accommodated twice in a dsDNA duplex without incurring any loss of stability and extrapolating from this observation and the results of modelling, it is conceivable that both can be multiplied several times within a dsDNA duplex. These new motifs extend the DNA recognition repertoire and may form the basis for a complete series of double‐headed nucleotides based on all 16 base combinations of the four natural nucleobases. In addition, both motifs can be used in the design of nanoscale DNA structures in which a specific duplex twist is required.