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.     

Protein-induced DNA bending: the role of phosphate neutralisation

An important component of protein–nucleic acid interactions is the formation of salt bridges between cationic amino acid side chains and the anionic phosphate groups of the nucleic acid. We have used molecular mechanics to study the energetic and conformational impact of such interactions. Firstly, crystallographic protein–nucleic acid complexes from the Protein Data Bank were analysed in terms of DNA curvature and the presence of salt bridges. For complexes where the DNA is significantly bent, the contribution of salt bridges to this curvature was modelled by studying the effect of neutralising the appropriate phosphate groups. The number and the distribution of salt bridges vary widely for different DNA binding motifs and appear to have very different effects on DNA. In the case of homeodomain, bZIP and helix–loop–helix proteins, salt bridges induce DNA bending, whereas for prokaryotic helix–turn–helix proteins the number of salt bridges is much smaller and little bending is found. By analysing the components of the DNA deformation energy involved in protein binding we show that salt bridges consistently increase the flexibility of the DNA backbone. Received: 1 September 2000 / Accepted: 5 January 2001 / Published online: 3 May 2001     

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.     

Sequence‐Specific DNA Recognition by Cyclic Pyrrole–Imidazole Cysteine‐Derived Polyamide Dimers

Pyrrole–imidazole (PI) polyamides bind to the minor groove of the DNA duplex in a sequence‐specific manner and thus have the potential to regulate gene expression. To date, various types of PI polyamides have been designed as sequence‐specific DNA binding ligands. One of these, cysteine cyclic PI polyamides containing two β‐alanine molecules, were designed to recognize a 7 bp DNA sequence with high binding affinity. In this study, an efficient cyclization reaction between a cysteine and a chloroacetyl residue was used for dimerization in the synthesis of a unit that recognizes symmetrical DNA sequences. To evaluate specific DNA binding properties, dimeric PI polyamide binding was measured by using a surface plasmon resonance (SPR) method. Extending this molecular design, we synthesized a large dimeric PI polyamide that can recognize a 14 bp region in duplex DNA.     

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.     

Alternative heterocycles for DNA recognition: the benzimidazole/imidazole pair

Boc-protected benzimidazole-pyrrole, benzimidazole-imidazole, and benzimidazole-methoxypyrrole amino acids were synthesized and incorporated into DNA binding polyamides, comprised of N-methyl pyrrole and N-methyl imidazole amino acids, by means of solid-phase synthesis on an oxime resin. These hairpin polyamides were designed to determine the DNA recognition profile of a side-by-side benzimidazole/imidazole pair for the designated six base pair recognition sequence. Equilibrium association constants of the polyamide-DNA complexes were determined at two of the six base pair positions of the recognition sequence by quantitative DNase I footprinting titrations on DNA fragments each containing matched and single base pair mismatched binding sites. The results indicate that the benzimidazole-heterocycle building blocks can replace pyrrole-pyrrole, pyrrole-imidazole, and pyrrole-hydroxypyrrole constructs while retaining relative site specifities and subnanomolar match site affinities. The benzimidazole-containing hairpin polyamides represent a novel class of DNA binding ligands featuring tunable target recognition sequences combined with the favorable properties of the benzimidazole type DNA minor groove binders.     

Analysis of noncovalent complexes between human telomeric DNA and polyamides containing N-methylpyrrole and N-methylimidazole by using electrospray ionization mass spectrometry

Electrospray ionization mass spectrometry (ESI-MS) was used to investigate noncovalent complexes formed between four novel polyamides containing N-methylpyrrole (Py) and N-methylimidazole (Im), and human telomeric DNA. Of the four polyamides investigated, PyPyPygammaImImImbetaDp (3) had the highest binding affinity towards the duplex d(TTAGGGTTAGGG/CCCTAACCCTAA) (D1). Results of competition analysis showed that the polyamides had binding affinities with D1 in the order PyPyPygammaImImImbetaDp (3)>PyPyPyPygammaPyImImPybetaDp (4)>PyPyPybetaImImImbetaDp (2)>ImImImbetaDp (1). MS/MS spectra confirmed that binding between D1 and the hairpin polyamides is more stable than that with the three-ring polyamides. By contrast, in the case of single-stranded d(TTAGGGTTAGGG)(D2), the binding order changes to ImImImbetaDp (1)>PyPyPygammaImImImbetaDp (3)>PyPyPybetaImImImbetaDp (2).     

N-甲基吡咯类聚酰胺的合成及其与DNA的相互作用

本研究主要是设计并合成了3个含有4个N-甲基吡咯的聚酰胺化合物(PyPyPyPyβDp,PyPyPyPyγDp, NO₂PyPyPyPyβDp),并使用ESI-MS法研究了其与DNA的相互作用.     

Determining Metal Ion Complexation Kinetics with Fluorescent Ligands by Using Fluorescence Correlation Spectroscopy

Fluorescence correlation spectroscopy (FCS) has been extensively used to measure equilibrium binding constants (K) or association and dissociation rates in many reversible chemical reactions across chemistry and biology. For the majority of investigated reactions, the binding constant was on the order of ∼100 M⁻¹, with dissociation constants faster or equal to 10³ s⁻¹, which ensured that enough association/dissociation events occur during the typical diffusion-determined transition time of molecules through the FCS detection volume. However, complexation reactions involving metal ions and chelating ligands exhibit equilibrium constants exceeding 10⁴ M⁻¹. In the present paper, we explore the applicability of FCS for measuring reaction rates of such complexation reactions, and apply it to binding of iron, europium and uranyl ions to a fluorescent chelating ligand, calcein. For this purpose, we exploit the fact that the ligand fluorescence becomes strongly quenched after binding a metal ion, which results in strong intensity fluctuations that lead to a partial correlation decay in FCS. We also present measurements for the strongly radioactive ions of ²⁴¹Am³⁺, where the extreme sensitivity of FCS allows us to work with sample concentrations and volumes that exhibit close to negligible radioactivity levels. A general discussion of the applicability of FCS to the investigation of metal-ligand binding reactions concludes our paper.     

Characterization of solution-phase DNA hybridization by fluorescence correlation spectroscopy: Rapid genotyping of C677T from methylenetetrahydrofolate reductase gene

In this paper, fluorescence correlation spectroscopy (FCS) was applied to measure the hybridization fraction of the ssDNA probe with its perfectly matched 146 mer ssDNA and a base mismatched 146 mer ssDNA from human methylenetetrahydrofolate reductase (MTHFR) gene. The ssDNA fragments in this study were obtained by asymmetric PCR techniques. The measurements were performed on a laboratory-built FCS system based on the two components fitting procedure. The obtained results showed that FCS could discriminate the difference of thermal stability between perfectly matched and mismatched DNA duplex, and be used to characterize the genotype of C677T in MTHFR gene. Our data illustrated that FCS was a useful tool for rapid screening of single point genetic mutations/polymorphisms (SNP) combined with DNA hybridization.     

特异性识别DNA的吡咯-咪唑多聚酰胺的研究进展

吡咯-咪唑多聚酰胺为一类人工合成的主要由五元杂环化合物N-甲基吡咯(Py)、N-甲基咪唑(Im)和N-甲基3-羟基吡咯(Hp)芳香氨基酸组成的,经酰胺键连接的人工小分子配体.它们具有与天然DNA结合蛋白相媲美的DNA特异性识别和结合能力.近20年来,对此类化合物的研究取得了重要进展,确定了简单的氨基酸对识别碱基对的规则,研究了多种方式连接的吡咯-咪唑多聚酰胺与DNA小沟结合模式,合成了多种双功能吡咯-咪唑多聚酰胺,且吡咯-咪唑多聚酰胺能穿过细胞膜,具有在体内外调节基因表达的作用。     

Surface plasmon resonance study on HIV-1 integrase strand transfer activity

Understanding the molecular mechanism of HIV-1 integrase (IN) activity is critical to find functional inhibitors for an effective AIDS therapy. A robust, fast, and sensitive method for studying IN activity is required. In this work, an assay for real-time label-free monitoring of the IN activity based on surface plasmon resonance was developed. This assay enabled direct monitoring of the integration of a viral doubled-stranded (ds) DNA into the host genome. The strand transfer reaction was detected by using two different DNA targets: supercoiled plasmid (pUC 19) and short palindrome oligonucleotide. The effect of the length of the DNA target on the possibility to monitor the actual process of the strand transfer reaction is discussed. The surface density of integrated ds-DNA was determined. IN binding to the oligonucleotide complexes and model DNA triplexes in the presence of various divalent ions as metal cofactors was investigated as well. The assay developed can serve as an important analytical tool to search for potential strand transfer reaction inhibitors as well as for the study of compounds interfering with the binding of ds long terminal repeats–IN complexes with the host DNA. HIV-1 integrase strand transfer activity was monitored in real time using a multichannel surface plasmon resonance biosensor. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

pH-induced intramolecular folding dynamics of i-motif DNA

Using the combination of fluorescence resonance energy transfer (FRET) and fluorescence correlation spectroscopy (FCS) technique, we investigate the mechanism and dynamics of the pH-induced conformational change of i-motif DNA in the bulk phases and at the single-molecule level. Despite numerous studies on i-motif that is formed from cytosine (C)-rich strand at slightly acidic pH, its detailed conformational dynamics have been rarely reported. Using the FRET technique to provide valuable information on the structure of biomolecules such as a protein and DNA, we clearly show that the partially folded species as well as the single-stranded structure coexist at neutral pH, supporting that the partially folded species may exist substantially in vivo and play an important role in a process of gene expression. By measuring the FCS curves of i-motif, we observed the gradual decrease of the diffusion coefficient of i-motif with increasing pH. The quantitative analysis of FCS curves supports that the gradual decrease of diffusion coefficient (D) associated with the conformational change of i-motif is not only due to the change in the intermolecular interaction between i-motif and solvent accompanied by the increase of pH but also due to the change of the shape of DNA. Furthermore, FCS analysis showed that the intrachain contact formation and dissociation for i-motif are 5-10 times faster than that for the open form. The fast dynamics of i-motif with a compact tetraplex is due to the intrinsic conformational changes at the fluorescent site including the motion of alkyl chain connecting the dye to DNA, whereas the slow intrachain contact formation observed from the open form is due to the DNA motion corresponding to an early stage interaction in the folding process of the unstructured open form.     

Single-molecule studies on DNA and RNA.

DNA and RNA are the most individual molecules known. Therefore, single-molecule experiments with these nucleic acids are particularly useful. This review reports on recent experiments with single DNA and RNA molecules. First, techniques for their preparation and handling are summarised including the use of AFM nanotips and optical or magnetic tweezers. As important detection techniques, conventional and near-field microscopy as well as fluorescence resonance energy transfer (FRET) and fluorescence correlation spectroscopy (FCS) are touched on briefly. The use of single-molecule techniques currently includes force measurements in stretched nucleic acids and in their complexes with binding partners, particularly proteins, and the analysis of DNA by restriction mapping, fragment sizing and single-molecule hybridisation. Also, the reactions of RNA polymerases and enzymes involved in DNA replication and repair are dealt with in some detail, followed by a discussion of the transport of individual nucleic acid molecules during the readout and use of genetic information and during the infection of cells by viruses. The final sections show how the enormous addressability in nucleic acid molecules can be exploited to construct a single-molecule field-effect transistor and a walking single-molecule robot, and how individual DNA molecules can be used to assemble a single-molecule DNA computer.     

DNA binding and cleavage activity of reduced amino-acid Schiff base complexes of cobalt(II), copper(II), and cadmium(II)

Three new reduced amino-acid Schiff base complexes, [Co(HL)₂(H₂O)₂] · 4H₂O (1), [Cu(HL)₂(H₂O)₂] · 2H₂O (2), and [Cd(HL)₂(H₂O)₃] · 2H₂O (3), where H₂L is the reduced Schiff-base ligand derived from the condensation of N-(4-hydroxybenzaldehyde) with L-glycine, have been synthesized and characterized by physico-chemical and spectroscopic methods. In these complexes, the two bidentate monoanionic Schiff base ligands coordinate the metal center through the secondary amine N atom and the carboxylate O atom. Water ligands complete a distorted octahedral (1, 2) or a pentagonal bipyramidal coordination geometry (3) around each metal center. The binding interactions of the complexes with CT-DNA have been investigated by UV–visible spectrophotometry and fluorescence quenching methods. The results show that these complexes bind to CT-DNA with an intercalative mode. In addition, DNA cleavage experiments have been also investigated by agarose gel electrophoresis. Complexes 1–3 show oxidative DNA cleavage activity in the presence of H₂O₂/sodium ascorbate and the reactive oxygen species responsible for the DNA cleavage is most likely singlet oxygen. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Discrimination of hairpin polyamides with an alpha-substituted-gamma-aminobutyric acid as a 5'-TG-3' reader in DNA minor groove

Pyrrole-imidazole (Py-Im) polyamides containing stereospecifically alpha-amino- or alpha-hydroxyl-substituted gamma-aminobutyric acid as a 5'-TG-3' recognition element were synthesized by machine-assisted Fmoc solid-phase synthesis. Their binding properties to predetermined DNA sequences containing a core binding site of 5'-TGCNCA-3'/3'-ACGN'GT-5' (N.N' = A.T, T.A, G.C, and C.G) were then systematically studied by surface plasmon resonance (SPR). SPR results revealed that the pairing of stereospecifically alpha-amino-/alpha-hydroxyl-substituted gamma-aminobutyric acids, (R or S)-alpha,gamma-diaminobutyric acid (gammaRN or gammaSN) and (R or S)-alpha-hydroxyl-gamma-aminobutyric acid (gammaRO or gammaSO), side-by-side with beta-alanine (beta) in such polyamides significantly influenced the DNA binding affinity and recognition specificity of hairpin polyamides in the DNA minor groove compared with beta/beta, beta/gamma, and gamma/beta pairings. More importantly, the polyamide Ac-Im-gammaSO-ImPy-gamma-ImPybetaPy-beta-Dp (beta/gammaSO) favorably binds to a hairpin DNA containing a core binding site of 5'-TGCNCA-3'/3'-ACGN'GT-5' (N.N' = A.T) with dissociation equilibrium constant (K(D)) of 1.9 x 10(-)(7) M over N.N' = T.A with K(D) = 3.7 x 10(-)(6) M, with a 19-fold specificity. By contrast, Ac-Im-gammaSN-ImPy-gamma-ImPybetaPy-beta-Dp (beta/gammaSN) binds to the above sequence with N.N' = A.T with K(D) = 8.7 x 10(-)(7) M over N.N' = T.A with K(D) = 8.4 x 10(-)(6) M, with a 9.6-fold specificity. The results also show that the stereochemistry of the alpha-substituent, as well as the alpha-substituent itself may greatly alter binding affinity and recognition selectivity of hairpin polyamides to different DNA sequences. Further, we carried out molecular modeling studies on the binding by an energy minimization method, suggesting that alpha-hydroxyl is very close to N3 of the 3'-terminal G to induce the formation of hydrogen bonding between hydroxyl and N3 in the recognition event of the polyamide Ac-Im-gammaSO-ImPy-gamma-ImPybetaPy-beta-Dp (beta/gammaSO) to 5'-TGCNCA-3'/3'-ACGN'GT-5' (N.N' = A.T). Therefore, SPR assays and molecular modeling studies collectively suggest that the (S)-alpha-hydroxyl-gamma-aminobutyric acid (gammaSO) may act as a 5'-TG-3' recognition unit.     

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.