Recognition Of Duplex DNA Research Articles

Triplex-forming properties and enzymatic incorporation of a base-modified nucleotide capable of duplex DNA recognition at neutral pH.

The sequence-specific recognition of duplex DNA by unmodified parallel triplex-forming oligonucleotides is restricted to low pH conditions due to a necessity for cytosine protonation in the third strand. This has severely restricted their use as gene-targeting agents, as well as for the detection and/or functionalisation of synthetic or genomic DNA. Here I report that the nucleobase 6-amino-5-nitropyridin-2-one (Z) finally overcomes this constraint by acting as an uncharged mimic of protonated cytosine. Synthetic TFOs containing the nucleobase enabled stable and selective triplex formation at oligopurine-oligopyrimidine sequences containing multiple isolated or contiguous GC base pairs at neutral pH and above. Moreover, I demonstrate a universal strategy for the enzymatic assembly of Z-containing TFOs using its commercially available deoxyribonucleotide triphosphate. These findings seek to improve not only the recognition properties of TFOs but also the cost and/or expertise associated with their chemical syntheses.

Design and synthesis of purine nucleoside analogues for the formation of stable anti-parallel-type triplex DNA with duplex DNA bearing the 5mCG base pair.

We herein demonstrated for the first time the direct recognition of duplex DNA bearing the 5-methyl-2′-deoxycytosine and 2′-deoxyguanosine base pair by triplex DNA formation. Triplex-forming oligonucleotides contained the novel artificial nucleoside analogues 2-amino-2′-deoxy-nebularine derivatives, and their molecular design, synthesis, and functional evaluation are described.

Modification of the aminopyridine unit of 2′-deoxyaminopyridinyl-pseudocytidine allowing triplex formation at CG interruptions in homopurine sequences

The antigene strategy based on site-specific recognition of duplex DNA by triplex DNA formation has been exploited in a wide range of biological activities. However, specific triplex formation is mostly restricted to homo-purine strands within the target duplex DNA, due to the destabilizing effect of CG and TA inversion sites where there is an absence of natural nucleotides that can recognize the CG and TA base pairs. Hence, the design of artificial nucleosides, which can selectively recognize these inversion sites with high affinity, should be of great significance. Recently, we determined that 2-amino-3-methylpyridinyl pseudo-dC (3MeAP-ΨdC) possessed significant affinity and selectivity toward a CG inversion site and showed effective inhibition of gene expression. We now describe the design and synthesis of new modified aminopyridine derivatives by focusing on small chemical modification of the aminopyridine unit to tune and enhance the selectivity and affinity toward CG inversion sites. Remarkably, we have newly found that 2-amino-4-methoxypyridinyl pseudo-dC (4OMeAP-ΨdC) could selectively recognize the CG base pair in all four adjacent base pairs and form a stable triplex structure against the promoter sequence of the human gene including multiple CG inversion sites.

An overview of recent advances in duplex DNA recognition by small molecules.

As the carrier of genetic information, the DNA double helix interacts with many natural ligands during the cell cycle, and is amenable to such intervention in diseases such as cancer biogenesis. Proteins bind DNA in a site-specific manner, not only distinguishing between the geometry of the major and minor grooves, but also by making close contacts with individual bases within the local helix architecture. Over the last four decades, much research has been reported on the development of small non-natural ligands as therapeutics to either block, or in some cases, mimic a DNA–protein interaction of interest. This review presents the latest findings in the pursuit of novel synthetic DNA binders. This article provides recent coverage of major strategies (such as groove recognition, intercalation and cross-linking) adopted in the duplex DNA recognition by small molecules, with an emphasis on major works of the past few years.

Modulation of Hoogsteen dynamics on DNA recognition

In naked duplex DNA, G–C and A–T Watson-Crick base pairs exist in dynamic equilibrium with their Hoogsteen counterparts. Here, we used nuclear magnetic resonance (NMR) relaxation dispersion and molecular dynamics (MD) simulations to examine how Watson-Crick/Hoogsteen dynamics are modulated upon recognition of duplex DNA by the bisintercalator echinomycin and monointercalator actinomycin D. In both cases, DNA recognition results in the quenching of Hoogsteen dynamics at base pairs involved in intermolecular base-specific hydrogen bonds. In the case of echinomycin, the Hoogsteen population increased 10-fold for base pairs flanking the chromophore most likely due to intermolecular stacking interactions, whereas actinomycin D minimally affected Hoogsteen dynamics at other sites. Modulation of Hoogsteen dynamics at binding interfaces may be a general phenomenon with important implications for DNA–ligand and DNA–protein recognition.

DNA-directed spatial assembly of photosynthetic light-harvesting proteins.

This manuscript describes the surface immobilization of a light-harvesting complex to prescribed locations directed by the sequence-selective recognition of duplex DNA. An engineered light-harvesting complex (RC-LH1) derived from Rhodopseudomonas (Rps.) palustris containing the zinc finger (ZF) domain zif268 was prepared. The zif268 domain directed the binding of zfRC-LH1 to target double-stranded DNA sequences both in solution and when immobilized on lithographically defined micro-patterns. Excitation energy transfer from the carotenoids to the bacteriochlorophyll pigments within zfRC-LH1 confirmed that the functional and structural integrity of the complex is retained after surface immobilization.

An isocytidine derivative with a 2-amino-6-methylpyridine unit for selective recognition of the CG interrupting site in an antiparallel triplex DNA.

Sequence-specific recognition of duplex DNA mediated by triple helix formation offers a potential basis for oligonucleotide therapy and biotechnology. However, triplex formation is limited mostly to homopurine strands, due to poor stabilization at CG or TA base pairs in the target duplex DNA sequences. Several non-natural nucleosides have been designed for the recognition of CG or TA base pairs within an antiparallel triplex DNA. Nevertheless, problems including low selectivity and high dependence on the neighboring bases remain unsolved. We thus synthesized N(2)-arylmethyl isodC derivatives and incorporated them into triplex-forming oligonucleotides (TFOs) for the selective recognition of the CG base pair within antiparallel triplex DNA. It was shown that an isodC derivative bearing a 2-amino-6-methylpyridine moiety (AP-isodC) recognizes the CG base pair with high selectivity in antiparallel triplex DNA irrespective of the flanking base pairs.

Inhibiting Gene Expression with Peptide Nucleic Acid (PNA)−Peptide Conjugates That Target Chromosomal DNA

Peptide nucleic acids (PNAs) are nonionic DNA/RNA mimics that can recognize complementary sequences by Watson-Crick base pairing. The neutral PNA backbone facilitates the recognition of duplex DNA by strand invasion, suggesting that antigene PNAs (agPNAs) can be important tools for exploring the structure and function of chromosomal DNA inside cells. However, before agPNAs can enter wide use, it will be necessary to develop straightforward strategies for introducing them into cells. Here, we demonstrate that agPNA-peptide conjugates can target promoter DNA and block progesterone receptor (PR) gene expression inside cells. Thirty-six agPNA-peptide conjugates were synthesized and tested. We observed inhibition of gene expression using cationic peptides containing either arginine or lysine residues, with eight or more cationic amino acids being preferred. Both 13 and 19 base agPNA-peptide conjugates were inhibitory. Inhibition was observed in human cancer cell lines expressing either high or low levels of progesterone receptor. Modification of agPNA-peptide conjugates with hydrophobic amino acids or small molecule hydrophobic moieties yielded improved potency. Inhibition by agPNAs did not require cationic lipid or any other additive, but adding agents to cell growth media that promote endosomal release caused modest increases in agPNA potency. These data demonstrate that chromosomal DNA is accessible to agPNA-peptide conjugates and that chemical modifications can improve potency.

High‐affinity triplex‐forming oligonucleotide target sequences in mammalian genomes

Site-specific recognition of duplex DNA by triplex-forming oligonucleotides (TFOs) provides a promising approach to manipulate mammalian genomes. A prerequisite for successful gene targeting using this approach is that the targeted gene must contain specific, high-affinity TFO target sequences (TTS). To date, TTS have been identified and characterized in only approximately 37 human or rodent genes, limiting the application of triplex-directed gene targeting. We searched the complete human and mouse genomes using an algorithm designed to identify high-affinity TTS. The resulting data set contains 1.9 million potential TTS for each species. We found that 97.8% of known human and 95.2% of known mouse genes have at least one potential high-affinity TTS in the promoter and/or transcribed gene regions. Importantly, 86.5% of known human and 83% of the known mouse genes have at least one TTS that is unique to that gene. Thus, it is possible to target the majority of human and mouse genes with specific TFOs. We found substantially more potential TTS in the promoter sequences than in the transcribed gene sequences or intergenic sequences in both genomes. We selected 12 mouse genes and 2 human genes critical for cell signaling, proliferation, and/or carcinogenesis, identified potential TTS in each, and determined TFO binding affinities to these sites in vitro. We identified at least one high-affinity, specific TFO binding site within each of these genes. Using this information, many genes involved in mammalian cell proliferation and carcinogenesis can now be targeted.

Recognition of chromosomal DNA by PNAs.

The recognition of cellular nucleic acids by synthetic oligonucleotides is a versatile strategy for regulating biological processes. The vast majority of published studies have focused on antisense oligonucleotides that target mRNA, but it is also possible to design antigene oligonucleotides that are complementary to chromosomal DNA. Antigene oligomers could be used to inhibit the expression of any gene or analyze promoter structure and the mechanisms governing gene regulation. Other potential applications of antigene oligomers include activation of expression of chosen genes or the introduction of mutations to correct genetic disease. Peptide nucleic acid (PNA) is a nonionic DNA/RNA mimic that possesses outstanding potential for recognition of duplex DNA. Here we describe properties of PNAs and the challenges for their development as robust antigene agents.

Synthesis and duplex DNA recognition studies of oligonucleotides containing a ureido isoindolin-1-one homo- N-nucleoside. A comparison of host–guest and DNA recognition studies

In an effort to construct non-natural bases to be used in triplex-based antigene DNA recognition strategies, a uriedo-isoindolin-1-one homo- N-nucleoside base was designed to bind the cytosine-guanine (CG) base pair. An organic soluble analogue of this base was shown to effectively complex CG (K assoc=740 M −1) in chloroform through formation of three hydrogen bonds (Mertz, E.; Mattei, S.; Zimmerman, S. C. Org. Lett. 2000, 2, 2931–2934). The novel nucleoside base was synthesized and successfully incorporated into oligonucleotides which were used in triple helix melting temperature studies. Low melting temperatures were observed when the isoindolin-1-one base was paired opposite CG as well as GC, TA, and AT, thus indicating that despite favorable recognition in model studies, the artificial base did not effectively recognize duplex DNA to form pyrimidine-purine-pyrimidine type triple helices.

Sequence-Universal Recognition of Duplex DNA by Oligonucleotides via Pseudocomplementarity and Helix Invasion

The well-known Watson-Crick complementarity rules, which were discovered 50 years ago, elegantly direct the specific pairing of two DNA single strands. On the contrary, once formed, the double-stranded (ds) DNA lacks such a simple and sequence-universal recognition principle, since most of the characteristic chemical groups of nucleobases are now buried deep inside the double helix, the major DNA form. We report a promising versatile approach for highly selective recognition of designated sites within dsDNA featuring considerable practical potential for a variety of molecular-biological, biotechnological, gene-therapeutic, and diagnostic applications. It may also have implications for prebiotic evolution of genetic machinery at the primordial stages of the origin of life. Our design synergistically employs the robust helix-invasion ability of recently developed DNA mimics and analogs, pseudocomplementary peptide nucleic acids and pseudocomplementary oligonucleotides, thus enabling the sequence-unrestricted recognition of chosen DNA duplexes by nucleobase oligomers. Using this basically general approach, we selectively tagged a unique mixed-base site on the target dsDNA fragment with streptavidin and/or multiply labeled this site with fluorophores via the primer-extension reaction.

Sequence-selective recognition of duplex DNA through covalent interstrand cross-linking: kinetic and molecular modeling studies with pyrrolobenzodiazepine dimers.

Members of a homologous series of pyrrolo[2,1-c][1,4]benzodiazepine (PBD) dimers with C8-O-(CH(2))(n)-O-C8' diether linkages (n = 3-6 for 2a-d, respectively) have been studied for their ability to interact with oligonucleotide duplexes containing potential target binding sites. The results confirm earlier predictions that the n = 3 analogue (2a, DSB-120) will covalently bind to a 5'-Pu-GATC-Py sequence by cross-linking opposite-strand guanines separated by 2 bp. Preference for this DNA sequence is shown using oligonucleotides with altered bases between and/or flanking these guanines. The more extended PBD dimer 2c (n = 5) can span an extra base pair and cross-link the 5'-Pu-GA(T/A)TC-Py sequence. The ability of each homologue to cross-link linear plasmid DNA has been determined, with a rank order that correlates with the reported order of in vitro cytotoxicity: n = 3 (2a) > n = 5 (2c) > n = 6 (2d) > n = 4 (2b). The n = 3 homologue (2a) is >300-fold more efficient at cross-linking DNA than the clinically used cross-linking agent melphalan under the same conditions. Kinetic studies reveal that the n = 3 and 5 dimers achieve faster cross-linking to plasmid DNA (108 and 81% cross-linking h(-1) microM(-1) at 37 degrees C, respectively), whereas the n = 4 and 6 homologues are significantly less efficient at 10.3 and 23% cross-linking h(-1) microM(-1), respectively. Alternating activity for the odd n and even n dimers is probably due to configurational factors governed by the spatial separation of the PBD subunits and the flexible character of the tethering linkage. Molecular modeling confirms the order of cross-linking reactivity, and highlights the role of linker length in dictating sequence recognition for this class of DNA-reactive agent.

Creation of Functional Recognition Molecules for Chemical Modification of Gene Expression

AbstractFor Abstract see ChemInform Abstract in Full Text.

Creation of functional recognition molecules for chemical modification of gene expression

Artificial molecules that exhibit specific recognition of duplex DNA have attracted great interest because of their potential application in the manipulation of gene expression. Specific chemical reactions to the target base within the predetermined site would secure selective inhibition at either translation or transcription reactions. A more interesting application would be to alter the reacted base structure to induce a point mutation. In our study, we have focused our efforts on: 1) development of new cross-linking molecules with high efficiency as well as high selectivity; 2) establishment of a new molecular basis for the formation of nonnatural triplexes; and 3) synthetic approaches to the new minor groove binders. This paper summarizes our recent results using two new functional molecules: 2-amino-6-vinylpurine derivatives as new cross-linking agents; and W-shaped nucleic acid analogues as new recognition molecules for the formation of nonnatural-type triplexes.

Promoter Use by ς38 (rpoS) RNA Polymerase: AMINO ACID CLUSTERS FOR DNA BINDING AND ISOMERIZATION

Sigma(38) is a non-essential but highly homologous member of the sigma(70) family of transcription factors. In vitro mutagenesis and in vivo screening were used to identify 22 critical amino acids in the promoter interaction domain of Escherichia coli sigma(38). Electrophoretic mobility shift assay studies showed that residues involved in duplex DNA binding largely segregated into distinct regions that coincided with those of sigma(70). However, the majority of these amino acids were in non-conserved positions. Analysis indicates that this region of the two sigma(s) probably has a common overall organization but differs in how its amino acids are used to form functional open complexes. Placement of the mutations on the known sigma(70) holoenzyme structure shows two clusters; one appears to be used for duplex DNA recognition and the other for the subsequent isomerization events. Permanganate assays for DNA melting support this view.

Examination of the DNA substrate selectivity of DNA cytosine methyltransferases using mass tagging.

The biological significance of cytosine methylation is as yet incompletely understood, but substantial and growing evidence strongly suggests that perturbation of methylation patterns, resulting from the infidelity of DNA cytosine methyltransferase, is an important component of the development of human cancer. We have developed a novel in vitro assay that allows us to quantitatively determine the DNA substrate preferences of cytosine methylases. This approach, which we call mass tagging, involves the labeling of target cytosine residues in synthetic DNA duplexes with stable isotopes, such as (15)N. Methylation is then measured by the formation of 5-methylcytosine (5mC) by gas chromatography/mass spectrometry. The DNA substrate selectivity is determined from the mass spectrum of the product 5mC. With the non-symmetrical duplex DNA substrate examined in this study we find that the bacterial methyltransferase HPA:II (duplex DNA recognition sequence CCGG) methylates the one methylatable cytosine of each strand similarly. Introduction of an A-C mispair at the methylation site shifts methylation exclusively to the mispaired cytosine residue. In direct competition assays with HPA:II methylase we observe that the mispaired substrate is methylated more extensively than the fully complementary, normal substrate, although both have one HPA:II methylation site. Through the use of this approach we will be able to learn more about the mechanisms by which methylation patterns can become altered.

Strand invasion by DNA-peptide conjugates and peptide nucleic acids

Peptide nucleic acids (PNAs) and conjugates between oligonucleotides and cationic peptides possess superior potential for strand invasion at complementary sequences. We discovered that oligonucleotide-peptide conjugates and PNAs fall into three classes based on their hybridization efficiency; i) those complementary to inverted repeats within AT-rich region hybridize with highest efficiency; ii) those complementary to areas adjacent to inverted repeats or near AT-rich regions hybridize with moderate efficiency; and iii) those complementary to other regions do not detectably hybridize. The correlations between oligomer chemistry, DNA target sequence, and hybridization efficiency that we report here have important implications for the recognition of duplex DNA.

Rules for Strand Invasion by Chemically Modified Oligonucleotides

Recognition of sequences within duplex DNA is a general strategy for probing DNA function and for disrupting gene expression. Peptide nucleic acids (PNAs) and conjugates between DNA oligonucleotides and cationic peptides possess superior potential for strand invasion at complementary sequences. To elucidate the rules underlying this phenomenon we examined hybridization to sequences throughout plasmid pUC19. We discovered that oligonucleotide−peptide conjugates and PNAs fall into three classes based on their hybridization efficiencies: (i) those complementary to inverted repeats within AT-rich region hybridize with highest efficiency; (ii) those complementary to areas adjacent to inverted repeats or near AT-rich regions hybridize with moderate efficiency; and (iii) those complementary to other regions do not detectably hybridize, with the exception of PNAs that have been modified to incorporate additional positive charge. Hybridization of oligonucleotide−peptide conjugates and PNAs was stringently dependent on target sequence and was most efficient at sequences within the promoter for β-lactamase or prior to the Escherichia coli origin of replication, suggesting that the sequences that regulate biological function may also be among the most susceptible to strand invasion. The correlations between oligomer chemistry, DNA target sequence, and hybridization efficiency that we report here have important implications for the recognition of duplex DNA in cell-free systems and for the selection of target sites for regulating gene expression within cells using synthetic molecules.

Novel Hoogsteen-like bases for configurational recognition of the T-A base pair by DNA triplex formation.

Effective sequence-specific recognition of duplex DNA is possible by triplex formation with natural oligonucleotides via Hoogsteen H-bonding. However, triplex formation is in practice limited to pyrimidine oligonucleotides binding duplex A-T or G-C base-pair DNA sequences specifically at homopurine sites in the major groove as T-A-T and C+.G-C triplets. Here we report the successful modeling of novel unnatural nucleosides that recognize the T-A DNA base pair by Hoogsteen interaction. Since the DNA triplex can be considered to assume an A-type or B-type conformation, these novel Hoogsteen nucleotides are tested within model A-type and B-type conformation triplex structures. A triplet consisting of the T-A base pair and one of the novel Hoogsteen nucleotides replaces the central T.A-T triplet in the triplex using the same deoxyribose-phosphodiester and base-deoxyribose dihedral angle configuration. The entire triplex is energy minimized and the presence of any structural or energetic perturbations due to the central triplet is assessed with respect to the unmodified energy-minimized (T.A-T)11 proposed starting structures. Incorporation of these novel triplets into both A-type and B-type natural tiplex structures provokes minimal change in the configuration of the central and adjacent triplets. The plan is to produce a series of Hoogsteen-like bases that preferentially bind the T-A major groove in either an A-type or B-type conformation. Selective recognition of the T-A major groove with respect to the G-C major groove, which presents similar keto and amine placement, is also assessed with configurational preference. Evaluation of the triplex solution structure by using these unnatural bases as binding conformational probes is a prerequisite to the further design of triplet forming bases.