Interaction of psoralen-derivatized oligodeoxyribonucleoside methylphosphonates with single-stranded DNA

Unique Crosslinking Properties of Psoralen-Conjugated Oligonucleotides Developed by Novel Psoralen N-Hydroxysuccinimide Esters

Psoralens and their derivatives, such as trioxsalen, have unique crosslinking features to DNA. However, psoralen monomers do not have sequence-specific crosslinking ability with the target DNA. With the development of psoralen-conjugated oligonucleotides (Ps-Oligos), sequence-specific crosslinking with target DNA has become achievable, thereby expanding the application of psoralen-conjugated molecules in gene transcription inhibition, gene knockout, and targeted recombination by genome editing. In this study, we developed two novel psoralen N-hydroxysuccinimide (NHS) esters that allow the introduction of psoralens into any amino-modified oligonucleotides. Quantitative evaluation of the photo-crosslinking efficiencies of the Ps-Oligos to target single-stranded DNAs revealed that the crosslinking selectivity to 5-mC is the unique feature of trioxsalen. We found that the introduction of an oligonucleotide via a linker at the C-5 position of psoralen can promote favorable crosslinking to target double-stranded DNA. We believe our findings are essential information for the development of Ps-Oligos as novel gene regulation tools.

Therapeutic application of sequence-specific binding molecules for novel genome editing tools

Genome editing has been expected to widely increase the available treatment options for various diseases and permit pharmaceutical interventions in previously untreatable conditions. The availability of genome editing tools was dramatically increased by the development of the CRISPR-Cas9 system. However, a number of issues limit the use of the CRISPR-Cas9 system and other gene-editing tools in the clinical treatment of diseases. This review summarized the history and types of genome editing tools and limitations of their use. In addition, the study addressed several next-generation technologies aiming to overcome the limitations of current gene therapy protocols in an effort to accelerate the clinical development of potential treatment options. This review has provided an extensive foundation of the current state of genome editing technology and its clinical development. This review also indicate that the study additionally highlighted the need for multidisciplinary approaches to overcome current bottlenecks in the development of genome editing.

Photocrosslinking of DNA using 4-methylpyranocarbazole nucleoside with thymine base selectivity

This report describes a novel photocrosslinker, 4-methylpyranocarbazole nucleoside (^MEPK), that can be induced to crosslink using visible light. Previously, we reported a visible light-responsive artificial nucleic acid, pyranocarbazole nucleoside (^PCX). ^MEPK can selectively photocrosslink to thymine bases in a complementary nucleic acid strand. It was synthesized by introducing a methyl group at the 4-position of ^PCX, and it can differentiate between thymine and cytosine. The previously reported visible light-responsive artificial nucleic acid ^PCX has a low synthetic yield. ^MEPK was synthesized by Pechmann condensation which suppressed by-product formation, making the synthesis more efficient, and resulting in a higher yield than that of ^PCX. ^MEPK is expected to have practical applications as a photocrosslinker that can be manipulated with visible light and that selectively targets thymine bases.

Critical Effect of Base Pairing of Target Pyrimidine on the Interstrand Photo-Cross-Linking of DNA via 3-Cyanovinylcarbazole Nucleoside

To evaluate the effect of base pairing of the target pyrimidine on the interstrand photo-cross-linking reaction of DNA via 3-cyanovinylcarbazole nucleoside ((CNV)K), a complementary base of target pyrimidine was substituted with noncanonical purine bases or 1,3-propandiol (S). As the decrease of the hydrogen bonds in the base pairing of target C accelerated the photo-cross-linking reaction markedly (3.6- to 7.7-fold), it can be concluded that the number of hydrogen bonds in the base pairing, i.e., the stability of base pairing, of the target pyrimidine plays a critical role in the interstrand photo-cross-linking reaction. In the case of G to S substitution, the highest photoreactivity toward C was observed, whose photoreaction rate constant (k = 2.0 s(-1)) is comparable to that of (CNV)K toward T paired with A (k = 3.5 s(-1)). This is the most reactive photo-cross-linking reaction toward C in the sequence specific interstrand photo-cross-linking. This might facilitate the design of the photo-cross-linkable oligodeoxyribonucleotides for various target sequences.

Photouncaged Sequence-specific Interstrand DNA Cross-Linking with Photolabile 4-oxo-enal-modified Oligonucleotides

DNA cross-linking technology is an attractive tool for the detection, regulation, and manipulation of genes. In this study, a series of photolabile 4-oxo-enal-modified oligonucleotides functionalized with photosensitive ο-nitrobenzyl derivatives were rationally designed as a new kind of photocaged cross-linking agents. A comprehensive evaluation of cross-linking reactions for different nucleobases in complementary strands under different conditions suggested that the modified DNA oligonucleotides tended to form interstrand cross-linking to nucleobases with the potential of thymidine > guanosine » cytidine ~ adenosine. Different from previous literature reports that cytidine and adenosine were preferential cross-linked nucleobases with 4-oxo-enal moieties, our study represents the first example of DNA cross-linking for T and G selectivity using 4-oxo-enal moiety. The cross-linked adducts were identified and their cross-linking mechanism was also illustrated. This greatly expands the applications of 4-oxo-enal derivatives in the studies of DNA damage and RNA structure

DNA photo-cross-linking using 3-cyanovinylcarbazole modified oligonucleotide with threoninol linker

3-Cyanovinylcarbazole modified D-threoninol ((CNV)D) was incorporated in oligodeoxyribonucleotide and tested for a photo-cross-linking reaction with complementary oligodeoxyribonucleotide. The photoreactivity was 1.8- to 8-fold greater than that of 3-cyanovinylcarbazole modified deoxyribose ((CNV)K) previously reported. From the results of melting analysis and circular dichroism spectroscopy of the duplexes, the relatively flexible structure of (CNV)D compared with (CNV)K might be advantageous for [2 + 2] photocycloaddition between the cyanovinyl group on the (CNV)D and pyrimidine base in the complementary strand.

Synthesis of Oligonucleotides Containing 4,5',8-Trimethylpsoralen at the 2'-O Position and Their Cross-Linking Properties with RNAs

4,5',8-Trimethylpsoralen-conjugated oligonucleotides have been used in the study of photo-cross-linking with target oligonucleotides and in the field of the photodynamic therapy. This unit describes synthetic procedures for oligonucleotides using 2'-O-methylphosphoramidite units and an adenosine phosphoramidite unit containing a 4,5',8-trimethylpsoralen derivative attached at the 2' position of an adenosine sugar moiety via an ethoxymethylene linkage. Procedures for obtaining the photo-cross-linking efficiency of 2'-O-methyloligonucleotides containing a 4,5',8-trimethylpsoralen derivative with a target oligonucleotide under UV irradiation conditions are also described, together with the procedure for preparation of (32)P-radiolabeled RNA.

Novel photodynamic effect of a psoralen-conjugated oligonucleotide for the discrimination of the methylation of cytosine in DNA

DNA methylation and demethylation significantly affect the deactivation and activation processes of gene expression significantly. In particular, C-5-methylation of cytosine in the CpG islands is important for the epigenetic modification in genes, which plays a key role in regulating gene expression. The determination of the location and frequency of DNA methylation is important for the elucidation of the mechanisms of cell differentiation and carcinogenesis. Here we designed a psoralen-conjugated oligonucleotide (PS-oligo) for the discrimination of 5-methylcytosine (5-mC) in DNA. The cross-linking behavior of psoralen derivatives with pyrimidine bases, such as thymine, uracil and cytosine has been well discussed, but there are no reports which have examined whether cross-linking efficiency of psoralen with cytosine would be changed with or without C-5 methylation. We found that the cross-linking efficiency of PS-oligo with target-DNA containing 5-mC was greatly increased compared to the case of target-DNA without 5-mC, approximately seven-fold higher. Here we report a new aspect of the photocross-linking behavior of psoralen with 5-mC that is applicable to a simple, sequence-specific and quantitative analysis for the discrimination of 5-mC in DNA, which can be applicable to study the epigenetic behavior of gene expressions.

Functional regulation of RNA-induced silencing complex by photoreactive oligonucleotides

We developed a novel method for regulation of RISC function by photoreactive oligonucleotides (Ps-Oligo) containing 2'-O-psoralenylmethoxyethyl adenosine (Aps). We observed that inhibitory effects of Ps-Oligos on RISC function were enhanced by UV-irradiation compared with 2'-O-methyl-oligonucleotide without Aps. These results suggest Ps-Oligo inhibited RISC function by cross-linking effect, and we propose that the concept described in this report may be promising and applicable one to regulate the small RNA-mediated post-transcriptional regulation.

Activation and alteration of base selectivity by metal cations in the functionality-transfer reaction for RNA modification

Previously, we reported that the 2-methylidene-1,3-diketone unit of 6-thioguanosine transferred selectively to the amino group of cytosine at pH 7.0 and that its selectivity was changed to the guanine base at pH 9.6. In this study, it was found that the functionality-transfer reaction enhanced selectivity for the guanine base in the presence of divalent transition metal cations such as Ni(2+) and Co(2+) at pH 7.4.

Specific regulation of point-mutated K-ras-immortalized cell proliferation by a photodynamic antisense strategy

It has been reported that point mutations in genes are responsible for various cancers, and the selective regulation of gene expression is an important factor in developing new types of anticancer drugs. To develop effective drugs for the regulation of point-mutated genes, we focused on photoreactive antisense oligonucleotides. Previously, we reported that photoreactive oligonucleotides containing 2'-O-psoralenylmethoxyethyl adenosine (2'-Ps-eom) showed drastic photoreactivity in a strictly sequence-specific manner. Here, we demonstrated the specific gene regulatory effects of 2'-Ps-eom on [(12)Val]K-ras mutant (GGT --> GTT). Photo-cross-linking between target mRNAs and 2'-Ps-eom was sequence-specific, and the effect was UVA irradiation-dependent. Furthermore, 2'-Ps-eom was able to inhibit K-ras-immortalized cell proliferation (K12V) but not Vco cells that have the wild-type K-ras gene. These results suggest that the 2'-Ps-eom will be a powerful nucleic acid drug to inhibit the expression of disease-causing point mutation genes, and has great therapeutic potential in the treatment of cancer.

Site-specific covalent modification of RNA guided by functionality-transfer oligodeoxynucleotides

Efficient methods for the covalent modification of large RNA molecules should find significance utility as innovative biological tools as well as therapeutic methods. In this study, the development of a general method for site-specific RNA modification guided by the functional ODN template has been investigated. The ODN probe containing 6-thioguanosine was modified by the methylenediketone derivative to form the S-functionalized ODN. Site-specific and cytosine-selective RNA modifications were achieved by the functionality-transfer reaction from the sulfur atom of the functionalized probe to the amino group of the cytosine base of the target strand. It was shown that the base and site selectivity were due to the close proximity of the reactants in the DNA-RNA duplexes.

Furan-modified oligonucleotides for fast, high-yielding and site-selective DNA inter-strand cross-linking with non-modified complements

Among the various types of DNA damage, inter-strand cross-links (ICL) represent one of the most cytotoxic lesions. Processes such as transcription and replication can be fully blocked by ICLs, as shown by the mechanism of action of some anticancer drugs. However, repair of ICLs can be a possible cause of resistance. To study the mechanisms of cross-link repair stable, site-specifically cross-linked duplexes are needed. We here report on the synthesis of site-specifically cross-linked DNA using an acyclic furan containing nucleoside. Selective in situ oxidation of the incorporated furan moiety generates a highly reactive oxo-enal that instantly reacts with the complementary base in a non-modified strand, yielding one specific stable cross-linked duplex species. Varying sequence context showed that a strong selectivity for cross-linking to either complementary A or complementary C is operating, without formation of cross-links to neighboring or distant bases. Reaction times are very short and high isolated yields are obtained using only one equivalent of modified strand. The formed covalent link is stable and the isolated cross-linked duplexes can be stored for several months without degradation. Structural characterization of the obtained ICL was possible by comparison to the natural mutagenic adducts of cis-2-butene-1,4-dial, a metabolite of furan primarily responsible for furan carcinogenicity.

Synthesis of antisense oligonucleotides containing 2'-O-psoralenylmethoxyalkyl adenosine for photodynamic regulation of point mutations in RNA

2'-O-psoralen-conjugated antisense oligonucleotide was able to recognize a point mutation of mRNA. It had outstanding ability to photo-cross-link only to oligoribonucleotides (ORN) having a point mutation. This type of antisense molecule is the only one of its kind so far. To give high photo-cross-linking efficiency and sequence selectivity to antisense molecules, we synthesized novel photo-reactive oligonucleotides (2'-Ps-xom) containing psoralen at the 2'-O-position adenosine via an ethoxymethylene (2'-Ps-eom), propoxymethylene (2'-Ps-pom) and butoxymethylene (2'-Ps-bom) linker, respectively. We evaluated the photo-cross-linking efficiency and sequence selectivity in photo-cross-linking of 2'-Ps-xom to the complementary ORN and to an ORN having a mismatch base. Among them, 2'-Ps-eom exhibited superior photo-cross-linking efficiency with high sequence selectivity.

Modification of the 5' terminus of oligonucleotides for attachment of reporter and conjugate groups

Reporter and conjugate groups can be added directly to the 5' terminus of oligonucleotides by appropriate modification. Conjugate groups can be used to increase the affinity of complementary strands, induce irreversible modification of target sequences, or enable sequences to recognize and permeate target cell membranes. This overview discusses the 5' modifications that can be used and strategies for the covalent attachment of ligands to the modified oligonucleotides. Step-by-step protocols for attachment of conjugate groups are given elsewhere in the series.

Synthesis and incorporation of a simple acyclic furan containing phosphoramidite

A novel furan containing phosphoramidite was synthesized and incorporated into model oligonucleotides. This glycol nucleic acid based building block contains a furan unit substituting the natural base, and can be used for post synthetic oligonucleotide modifications by orthogonal chemistries such as Schiff base formation after in situ oxidation or Diels-Alder cycloadditions.

Selective photo-cross-linking of 2'-O-psoralen-conjugated oligonucleotide with RNAs having point mutations

It has been reported that point mutations in genes are responsible for various cancers and the selective regulation of the gene expression is an important issue to develop a new type of anticancer drugs. In this report, we present a new type of antisense molecule that photo-cross-links to an oligoribonucleotide having a point mutation site in a sequence specific manner. 2'-O-psoralen-conjugated adenosine was synthesized in four steps from adenosine and introduced in the middle of an oligodeoxyribonucleotide (2'-Ps-oligo). Compared with 5'-O-psoralen-conjugated oligodeoxyribonucleotide (5'-Ps-oligo), which has a psoralen at the 5'-end, 2'-Ps-oligo more selectively photo-cross-linked to a pyrimidine base of the site of alteration from purine to pyrimidine in the oligoribonucleotide.

Photo-cross-linked oligonucleotide duplex as a decoy-DNA for inhibition of restriction endonuclease activity

As a novel type of regulator molecule for DNA-recognizing proteins, a photo-cross-linked oligonucleotide duplex was designed and synthesized. The molecule regulated the activity of a restriction endonuclease by being recognized as a substrate. This type of regulating molecule is regarded as a decoy-DNA. 4,5',8-[4-Aminoethylaminomethyl]-trioxalen (aeAMT) was conjugated with an oligodeoxyribonucleotide (ODN) at the 5'-end and the aeAMT was cross-linked with the thymine residue of the complementary oligonucleotide upon UVA irradiation. The terminally cross-linked oligonucleotides, singly clipped (SC) decoy-DNA, acquired thermal stability. An oligonucleoside phosphorothioate (OPT) was also introduced as one or both components, yielding three types of decoy-DNAs, SC-ODN-ODN (SC.DD), SC-OPT-ODN (SC.SD), and SC-OPT-OPT (SC.SS). The SC decoy-DNAs inhibited the function of the restriction endonuclease, AatII, in a sequence-specific and concentration-dependent manner with an appreciable IC50 value (1.3 microM for SC.DD, 0.016 microM for SC.SD, 0.002 microM for SC.SS). The SC decoy-DNAs were found to be effective for regulating the DNA recognizing proteins.

A new reactive nucleoside analogue for highly reactive and selective cross-linking reaction to cytidine under neutral conditions

We have already demonstrated that the oligonucleotides DNA (ODNs) bearing a 2-amino-6-vinylpurine derivative (1) exhibited efficient interstrand cross-linking to cytidine selectively. In this study, a new reactive nucleoside analogue, 2-amino-6-(1-ethylsulfoxy)vinylpurine derivative (7), was designed based on a computational method to achieve high and selective alkylation with cytidine under neutral conditions. It has been demonstrated that the ODN (13) bearing 2-amino-6-(1-ethylsulfoxy)vinylpurine achieved highly selective and efficient cross-linking to cytidine under neutral conditions.

Neutral liposome-mediated delivery process of fluorescein-modified oligonucleotides in cultured human keratinocytes

We propose a model of the intracellular delivery process in which fluorescein-labeled natural oligonucleotides (F-DNA) are transferred into the nuclei of cultured human keratinocytes. By encapsulation in neutral multilamellar lecithin liposomes, the F-DNA appeared to be protected against intracellular interactions with cellular materials and nuclease attacks in the cytoplasm during the process. The intracellular behavior of F-DNA and fluorescent phospholipid-labeled liposomes was observed by means of fluorescence analysis. Results showed that: F-DNA encapsulated in neutral multilamellar liposomes reached the cellular nuclei more efficiently than either free F-DNA, or F-DNA in unilamellar liposomes; the liposomal membranes appeared to be left in the cytoplasm. The reaction of F-DNA with complementary DNA was suggested by a rapid quenching of the fluorescence in the nucleus. In addition, the fluorescence decrease was evidently suppressed in the cytoplasm, indicating a protective effect of the neutral multilamellar liposomes against the interaction of F-DNA with cytoplasmic materials. The application of these findings to 'photo'-antisense studies has been discussed, where suppression of a gene expression is attempted by using oligonucleotide-attached fluorescein with the aid of a photo-induced covalent binding property.

Active oligonucleotides incorporating alkylating an agent as potential sequence- and base selective modifier of gene expression

A number of cross-linking (alkylating) agents have been developed and incorporated into the oligonulceotides for sequence selective control of gene expression. Recently, potential application of such active oligonucleotides has been expanding from use for improvement of inhibition efficiency to new biotechnology that may enable chemical alteration of genetic information. These interests in active oligonucleotides have encouraged the generation of new cross-linking agents that exhibit high efficiency for application of either in vitro or in vivo. This mini review summarizes structures of alkylating agents, in particular, a new basic skeleton for cross-linking, a 2'-deoxyribose derivative of 2-amino-6-vinylpurine that has been recently developed by the author's group. The 2-amino-6-vinylpurine has been shown to form a complex with cytidine under acidic conditions, and brings the vinyl and the amino reactive groups into proximity to achieve efficient alkylation. A new strategy was designed so that the reactivity of 2-amino-6-vinylpurine can be induced from the corresponding phenylsulfoxide derivative within a duplex with the complementary strand. The validity of the new strategy has been proven by achievement of cytidine-selective cross-linking with remarkably efficiency.

Photodynamic antisense regulation of human cervical carcinoma cell growth using psoralen-conjugated oligo(nucleoside phosphorothioate)

The antisense strategy has been applied to regulate gene expression in a sequence specific manner, which enables suppression of the proliferation of cancer cells and exploration of the functions of unknown genes. In order to generalize and to enhance the ability of the strategy, functionalization of antisense DNAs was done using a photo-crosslinking reagent, 4,5',8-trimethylpsoralen, and the possibility of photodynamic antisense regulation of gene expression was examined. Psoralen-conjugated oligo(nucleoside phosphorothioate)s (Ps-S-oligo) were prepared and used to inhibit the proliferation of human cervical carcinoma cells. Upon UVA irradiation of Ps-S-oligo treated cells, Ps-S-oligo complementary to the initiation codon region (Ps-P-As) of HPV18-E6*-mRNA of human cervical carcinoma cells inhibited drastically the cell growth (IC(50)=16 nM). In contrast, Ps-S-oligo with mismatched sequences and scrambled one showed lesser inhibitory effects than Ps-P-As. These results showed that the inhibition by Ps-S-oligo was dependent on (a) sequence, (b) UVA irradiation, (c) concentration and (d) cell line. The amount of intact HPV18-E6*-mRNA was decreased in a sequence dependent manner, indicating that the antiproliferative effect of Ps-P-As was an antisense manner. The psoralen-conjugated antisense DNA has significant potential to regulate gene expression, which may provide useful information to explore the novel gene regulating reagents.

Molecular mechanisms of action of antisense drugs

Given the progress reported during the past decade, a wide range of chemical modifications may be incorporated into potential antisense drugs. These modifications may influence all the properties of these molecules, including mechanism of action. DNA-like antisense drugs have been shown to serve as substrates when bound to target RNAs for RNase Hs. These enzymes cleave the RNA in RNA/DNA duplexes and now the human enzymes have been cloned and characterized. A number of mechanisms other than RNase H have also been reported for non-DNA-like antisense drugs. For example, activation of splicing, inhibition of 5'-cap formation, translation arrest and activation of double strand RNases have all been shown to be potential mechanisms. Thus, there is a growing repertoire of potential mechanisms of action from which to choose, and a range of modified oligonucleotides to match to the desired mechanism. Further, we are beginning to understand the various mechanisms in more detail. These insights, coupled with the ability to rapidly evaluate activities of antisense drugs under well-controlled rapid throughput systems, suggest that we will make more rapid progress in identifying new mechanisms, developing detailed understanding of each mechanism and creating oligonucleotides that better predict what sites in an RNA are most amenable to antisense drugs of various chemical classes.

Synthesis and hybridization properties of the conjugates of oligonucleotides and stabilization agents--II

New pyranone derivatives having tri- or pentamethylenamine linker functions were synthesized. These derivatives were covalently attached through the 5'-phosphoramide linkage to heptanucleotide pd(CCAAACA). Complementary complexes of the octanucleotide pd(TGTTTGGC) and above oligonucleotide conjugates were tested for their thermodynamic response. The Tm data and thermodynamic parameters for complex formation have demonstrated the ability of chromone (gamma-pyrone) and coumarin (alpha-pyrone) derivatives to stabilize strongly 7-mer/8-mer complementary complex, most likely through the stacking interaction of the pyran aromatic system with the neighboring nucleotide bases. The effect of chromone (or coumarin) derivatives on the stability of the oligonucleotide complexes (delta delta G at 37 degrees C ranged from -1.0 to -1.7 kcal/mol) was shown to be comparable to the effect of one nucleotide base pair and similar to the effect (delta delta G at 37 degrees C ranged from -1.5 to -2.0 kcal/mol) found for acridineoligonucleotide conjugates served in this study as a reference.

Site-specific and photo-induced alkylation of DNA by a dimethylanthraquinone-oligodeoxynucleotide conjugate

A dialkyl-substituted anthraquinone derivative was synthesized and ligated to a sequence-directing oligodeoxynucleotide to examine its efficiency and specificity for cross-linking to complementary sequences of DNA. The anthraquinone appendage stabilized spontaneous hybridization of the target and probe sequences through non-covalent interactions, as indicated by thermal denaturation studies. Covalent modification of the target was induced by exposure to near UV light (lambda > 335 nm) to generate cross-linked duplexes in yields as great as 45%. Reaction was dependent on the first unpaired nucleotide extended beyond the duplex formed by association of the target and probe. A specificity of C > T > A = G was determined for modification at this position. The overall site and nucleotide selectivity seems to originate from the chemical requirements of cross-linking and does not likely reflect the dominant solution structure of the complex prior to irradiation.

Solution structure of oligonucleotides covalently linked to a psoralen derivative

Psoralen (pso) was attached via its C-5 position to the 5'-phosphate group of an oligodeoxynucleotide d(TAAGCCG) by a hexamethylene linker (m6). Complex formation between pso-m6-d(TAAGCCG) and the complementary strands d(CGGCTTA)[7-7mer] or d(CGGCTTAT)[7-8mer] was investigated by nuclear magnetic resonance in aqueous solution. Structural informations derived from DQF-COSY and NOESY maps, revealed that the mini double helix adopts a B-form conformation and that the deoxyriboses preferentially adopt a C2'-endo conformation. The nOe connectivities observed between the protons of the bases or the sugars in each duplex, and the protons of the psoralen and the hexamethylene chain, led us to propose a model involving an equilibrium between two conformations due to different locations of the psoralen. Upon UV-irradiation, the psoralen moiety cross-linked the two DNA strands at the level of 5'TpA3' sequences. NMR studies of the single major photo-cross-linked duplex pso-m6-d(TAAGCCG) and d(CGGCTTA) were performed. The stereochemistry of the diadduct is indeed cis-syn at both cyclobutane rings. In addition, the effects of this diadduct on the helical structure are analyzed in detail.

Helix-stabilizing compounds CC-1065 and U-71,184 bind to RNA-DNA and DNA-DNA duplexes containing modified internucleotide linkages and stabilize duplexes against thermal melting

CC-1065 and U-71,184 bind and hyperstabilize DNA duplexes, but little is known about their effects on nucleic acid duplexes of different structure. A 20 mer DNA sequence (5'-TTACTTCAGTTATGAGACCA) containing a drug binding sequence (5'-AGTTA) was selected as the target sequence, and this was duplexed with complementary antisense sequences containing phosphodiester (PO), phosphorothioate (PS), and methylphosphonate (MP) bonds. The duplexes containing PO or PS bound 2 CC-1065 molecules per duplex, presumably at both the target site and at a lower affinity site (5'-AGTAA) on the antisense strand. The duplex containing MP bound only 1 CC-1065, and all duplexes bound only 1 U-71,184. Both CC-1065 and U-71,184 bound to 20 mer duplexes comprised of oligo(dA)-oligo(dT) (2.5 and 2 drugs per duplex, respectively) and poly(rA)-oligo(dT) (1 drug per 20 base pairs). CC-1065 also bound to duplexes between the PO- or PS-based antisense structures and a complementary synthetic 20 mer RNA sequence, with about 1 drug per duplex in each case. CC-1065 increased the Tm for the 20 mer DNA duplexes 17 to 29 degrees C, and the corresponding values for U-71,184 ranged from 7 to 19 degrees C. CC-1065 raised the Tm of oligo(dA)-oligo(dT) and poly(rA)-oligo(dT) 29 degrees C. U71,184 increased the Tm for oligo(dA)-oligo(dT) 30 degrees C but did not significantly elevate the Tm for the corresponding RNA-DNA duplex. The results show that CC-1065 and U-71,184 are capable of binding and stabilizing a variety of nucleic acid duplexes. These agents or their analogs may become useful ligands for antisense oligonucleotide applications.

Relative contribution of photo-addition, helper oligonucleotide and RNase H to the antisense effect of psoralen-oligonucleotide conjugates, on in vitro translation of Leishmania mRNAs

We investigated the properties of two antisense oligonucleotides, 11 alpha Pso and 14TMP, 11 and 14 nucleotides long, respectively, and conjugated to psoralen derivatives. These oligonucleotides were complementary to the mini-exon sequence of Leishmania amazonensis. Upon ultraviolet (UV) irradiation these oligomers were selectively cross-linked to DNA or RNA target sequences, either 14 or 35 nucleotides long. The yield of photo-addition was much lower on the longer targets than on the shorter ones, due to the presence of a hairpin structure. The co-addition of a helper oligonucleotide, whose binding site, on the 35-mer, was adjacent to that of the psoralen-derivatized antisense oligomer, improved the cross-linking efficiency. We then determined the effect of 14TMP on in vitro translation of Leishmania mRNA in cell-free extracts. Non-irradiated antisense oligonucleotide/mRNA complexes reduced the protein synthesis in wheat germ extract but not in rabbit reticulocyte lysate. Conversely, UV irradiation induced a 14TMP-dependent reduction of translation in reticulocyte lysate whereas the inhibition was not improved in the wheat germ extract. These results are discussed with respect to the involvement of RNase-H in the oligonucleotide-mediated effect on protein synthesis.

Effect of target structure on cross-linking by psoralen-derivatized oligonucleoside methylphosphonates

A series of psoralen-derivatized oligodeoxyribonucleoside methylphosphonates were examined for their abilities to cross-link to DNA and RNA oligonucleotide targets. These targets were designed to have either a random coil or a hairpin structure in solution. The methylphosphonate oligomers cross-linked with approximately the same rates to the random coil DNA and RNA targets, although the extent of cross-linking to the DNA target was higher than that to the RNA target. For a given methylphosphonate sequence, cross-linking decreased as the temperature increased, and this behavior paralleled the interaction of the oligomer with the target as determined by ultraviolet melting experiments. The oligomers also cross-linked efficiently with the DNA hairpin target, but little or no cross-linking was observed with the RNA hairpin. In the case of these hairpin targets, the extent of cross-linking was dependent upon the location of the oligomer binding site relative to the stem and loop regions of the hairpin. The lack of reactivity with the RNA hairpin may be due to the high stability of the stem of this target versus that in the DNA target and the relatively lower efficiency of binding of the methylphosphonates to RNA versus DNA targets. The sequences of the oligomers are complementary to vesicular stomatitis virus M-protein mRNA. One of the oligomers was tested, and was found to cross-link at 20 degrees C to VSV N-mRNA to approximately the same extent as observed for cross-linking with the random coil RNA target, suggesting that the mRNA binding site for the oligomer most likely is in a somewhat open conformation.(ABSTRACT TRUNCATED AT 250 WORDS)

Site-specific targeting of psoralen photoadducts with a triple helix-forming oligonucleotide: characterization of psoralen monoadduct and crosslink formation

A polypurine tract in the supF gene of bacteriophage lambda (base pairs 167-176) was selected as the target for triple helix formation and targeted mutagenesis by an oligopurine (5'-AGGAAGGGGG-3') containing a chemically linked psoralen derivative (4'-hydroxymethyl-4,5',8-trimethylpsoralen) at its 5' terminus (psoAG10). The thymines at base pairs 166 and 167, a 5'ApT site, were targeted for photomodification. Exposure of the triple helical complex to long wavelength ultraviolet radiation led to the covalent binding of psoAG10 to the targeted region in the supF gene and to the induction of site-specific mutations. We report here experiments to characterize the photomodification of the targeted region of the supF gene in the context of triple helix formation. An electrophoretic mobility-shift assay showed that, at low radiation doses, monoadducts at base pair 166 were the major photoadducts. At higher doses the monoadducts were converted to crosslinks between base pairs 166 and 167. HPLC analysis of enzymatically hydrolyzed photoreaction mixtures was used to confirm the electrophoresis results. A strong strand preference for specific photoadduct formation was also detected.

Interactions of psoralen-derivatized oligodeoxyribonucleoside methylphosphonates with vesicular stomatitis virus messenger RNA

The ability of oligonucleotides to interact selectively with their targets is an important consideration in the design of antisense oligonucleotides. This is especially important in the case of antisense oligomers, such as psoralen-derivatized oligomers, which can irreversibly bind to their targets. We have studied the interactions of a series of psoralen-derivatized antisense oligonucleoside methylphosphonates with the mRNAs of vesicular stomatitis virus (VSV), mRNAs that have a high degree of sequence homology. Cross-linking reactions were carried out under conditions of low ionic strength in order to reduce mRNA secondary structure. A 12-mer, whose sequence was complementary to VSV M-mRNA and partially complementary to sequences found in N, NS, and G mRNA cross-linked extensively to N-message. On the other hand, 16-mers whose sequences were uniquely complementary to binding sites on N- or M-mRNA specifically and efficiently cross-linked to their targeted mRNAs over the temperature range 0 degree to 37 degrees C. A reverse transcriptase-catalyzed primer extension assay was used to show that one of the N-specific oligomers cross-linked at the expected site on N-mRNA and to estimate the extent of cross-linking. The results demonstrate that psoralen-derivatized oligonucleoside methylphosphonates can cross-link in a sequence-specific manner if the sequences of these oligomers are chosen carefully so as to avoid extensive partial complementarity with other mRNA sequences.

Antiviral effect of oligo(nucleoside methylphosphonates) complementary to the herpes simplex virus type 1 immediate early mRNAs 4 and 5

We have previously shown that an oligo(nucleoside methylphosphonate) (deoxynucleoside methylphosphonate residues in italics) complementary to the acceptor splice junction of herpes simplex virus type 1 (HSV-1) immediate-early (IE) pre-mRNAs 4,5 [d(TpTCCTCCTGCGG)], causes sequence-specific inhibition of virus growth in infected cell cultures (Smith et al., 1986; Kulka et al., 1989). Here we report a similar inhibition of HSV-1 growth by oligo(nucleoside methylphosphonates) complementary to the splice donor site of HSV-1 IE pre-mRNAs 4,5 [d(GpCTTACCCGTGC)] and to the translation initiation site of IE4 mRNA [d(ApATGTCGGCCAT)]. An oligomer complementary to the translation initiation site of IE5 mRNA [d(GpGCCCACGACAT)] or an unrelated oligomer [d(GpCGGGAAGGCAC)] did not inhibit virus growth. IC50 values were 20, 25 and 20 microM for d(TpTCCTCCTGCGG), d(GpCTTACCCGTGC) and d(ApATGTCGGCCAT) respectively. In infected BALB/c mice d(TpTCCTCCTGCGG) caused a significant decrease in HSV-1 growth (82% inhibition at 500 microM). A psoralen-derivative of d(TpTCCTCCTGCGG) that binds covalently to complementary sequences after exposure to 365 nm irradiation, inhibited HSV-1 growth (86-91%) at a 10-fold lower concentration than the non-derivatized oligomer. The inhibition was sequence-specific and significantly lower (27%) for HSV-2 that differs from HSV-1 in 7 of the 12 bases targeted by d(TpTCCTCCTGCGG). Virus growth was not inhibited by d(GpGCCCACGACAT). The data suggest that oligo(nucleoside methylphosphonates) may be effective antiviral agents.

A novel strategy for site-directed chemical reactions in single stranded DNA--absorption and NMR spectroscopic studies of model compounds

A new and simple model enabling a chemical species to be brought to a preselected site in single strand DNA is reported. Two oligonucleotides containing a propanediol linkage were hybridized to their complementary sequences with an extra-base opposite the propanediol derivative. Absorption studies results shown that the addition of a bisacridine derivative strongly increased the stabilities of both duplexes when added in a 1:1 ratio. NMR studies on one of these duplexes brought evidence of the intercalation of the bisacridine at the position involving the propanediol linkage. These results suggest that this system could be used to target a specific reaction at a preselected position using the bisacridine derivative as carrier for the reactive species.

Oligodeoxynucleotide-directed photo-induced cross-linking of HIV proviral DNA via triple-helix formation

The HIV proviral genome contains two copies of a 16 bp homopurine.homopyrimidine sequence which overlaps the recognition and cleavage site of the Dra I restriction enzyme. Psoralen was attached to the 16-mer homopyrimidine oligonucleotide, d5'(TTTTCT-TTTCCCCCCT)3', which forms a triple helix with this HIV proviral sequence. Two plasmids, containing part of the HIV proviral DNA, with either one (pLTR) or two (pBT1) copies of the 16-bp homopurine.homopyrimidine sequence and either 4 or 14 Dra I cleavage sites, respectively, were used as substrates for the psoralen-oligonucleotide conjugate. Following UV irradiation the two strands of the DNA targeted sequence were cross-linked at the triplex-duplex junction. The psoralen-oligonucleotide conjugate selectively inhibited Dra I enzymatic cleavage at sites overlapping the two triple helix-forming sequences. A secondary triplex-forming site of 8 contiguous base pairs was observed on the pBT1 plasmid when binding of the 16 base-long oligonucleotide was allowed to take place at high oligonucleotide concentrations. Replacement of a stretch of six cytosines in the 16-mer oligomer by a stretch of six guanines increased binding to the primary sites and abolished binding to the secondary site under physiological conditions. These results demonstrate that oligonucleotides can be designed to selectively recognize and modify specific sequences in HIV proviral DNA.

Specific inhibition of transcription by triple helix-forming oligonucleotides

Homopyrimidine oligonucleotides bind to the major groove of a complementary homopyrimidine.homopurine stretch by triple helix formation. The bla gene from transposon Tn3 contains a homopyrimidine.homopurine sequence of 13 base pairs located just downstream of the RNA polymerase binding site. A 13-mer homopyrimidine oligonucleotide targeted to this sequence was tested for its effect on transcription of the bla gene in vitro. We show that the consequence of triple helix formation in front of the Escherichia coli RNA polymerase-promoter complex is to block the holoenzyme at its start site during a period that is dependent on temperature. The temperature dependence of transcription inhibition shows a direct correlation between this effect and the stabilization of the triple helix. Substitution of 5-methylcytosine to cytosine in the 13-mer oligonucleotide enhances triplex stability and transcription inhibition. Transcription inhibition by this synthetic repressor was also confirmed by footprinting studies demonstrating its specificity of action. The 13-mer oligonucleotide containing a psoralen derivative covalently linked to its 5' end shows an irreversible and specific inhibition of transcription initiation after exposure to light of wavelength greater than 310 nm.