Psoralen photo-cross-linking by triplex-forming oligonucleotides at multiple sites in the human rhodopsin gene.

Targeting DNA damage by triplex-forming oligonucleotides (TFOs) represents a way of modifying gene expression and structure and a possible approach to gene therapy. We have determined that this approach can deliver damage with great specificity to sites in the human gene for the G-protein-linked receptor rhodopsin, mutations of which can lead to the genetic disorder autosomal dominant retinitis pigmentosa. We have introduced DNA monoadducts and interstrand cross-links at multiple target sites within the gene using TFOs with a photoactivatable psoralen group at the 5'-end. The extent of formation of photoadducts (i.e., monoadducts and cross-links) was measured at target sites with a 5'-ApT sequence at the triplex-duplex junction and at a target site with 5'-ApT and 5'-TpA sequences located four and seven nucleotides away, respectively. To improve psoralen reactivity at more distant sites, psoralen moieties were attached to TFOs with nucleotide "linkers" from two to nine nucleotides in length. High-affinity binding was maintained with linkers of up to 10 nucleotides, but affinities tended to decrease somewhat with increasing linker length due to faster dissociation kinetics. DNase I footprinting indicated little, if any, interaction between linkers and the duplex. Psoralen-TFO conjugates formed DNA cross-links with high efficiency (56-65%) at 5'-ApT sequences located at triplex junctions. At a 5'-ApT site four nucleotides away, the efficiency varied with linker length; a four-nucleotide linker gave the highest efficiency. Duplexes with 5'-TpA and 5'-ApT sites two nucleotides away, in otherwise identical sequences, were cross-linked with efficiencies of 56 and 38%, respectively. These results indicate that TFO-linker-psoralen conjugates allow simultaneous, efficient targeting of multiple sites in the human rhodopsin gene.     

Triplex staples: DNA double-strand cross-linking at internal and terminal sites using psoralen-containing triplex-forming oligonucleotides

A method has been developed to attach 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen to the 5 position of thymine bases during solid-phase oligonucleotide synthesis. UV irradiation of triplex-forming oligonucleotides (TFOs) containing internally attached psoralens produces photoadducts at TpA steps within target duplexes, thus relaxing the constraints on selection of psoralen target sequences. Photoreaction of TFOs containing two psoralens, located at the 5'- and 3'-ends, has been used to create double-strand cross-links (triplex staples) at both termini of the TFO. Such complexes have no free single-stranded ends. TFOs containing 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen, 3-methyl-2-aminopyridine, and 5-(3-aminoprop-2-ynyl)deoxyuridine formed photoadducts with target duplexes under near-physiological conditions.     

In vivo persistence of DNA triple helices containing psoralen-conjugated oligodeoxyribonucleotides.

Triple helices represent an attractive method for modulating specific gene expression. In particular, cross-linking between a triplex-forming oligonucleotide (TFO) and its duplex DNA target, typically through the formation of psoralen photoadducts, allows efficient blocking of elongation by RNA polymerases in vitro. However, in vivo, this approach is limited by DNA repair of the photoadduct. Here we describe the use of an oligodeoxyribonucleotide 19mer psoralen-modified TFO to form covalent linkages between an oligonucleotide and both strands of the targeted duplex DNA, thereby efficiently blocking expression of a luciferase reporter gene. Most importantly, we demonstrate that both the psoralen cross-link and the purine-motif triplex remained intact for at least 72 h post-transfection, indicating that such species can persist for an extended period of time in vivo. These findings support the feasibility of an antigene approach for the therapeutic regulation of specific gene expression.     

Triple-helix formation induces recombination in mammalian cells via a nucleotide excision repair-dependent pathway

The ability to stimulate recombination in a site-specific manner in mammalian cells may provide a useful tool for gene knockout and a valuable strategy for gene therapy. We previously demonstrated that psoralen adducts targeted by triple-helix-forming oligonucleotides (TFOs) could induce recombination between tandem repeats of a supF reporter gene in a simian virus 40 vector in monkey COS cells. Based on work showing that triple helices, even in the absence of associated psoralen adducts, are able to provoke DNA repair and cause mutations, we asked whether intermolecular triplexes could stimulate recombination. Here, we report that triple-helix formation itself is capable of promoting recombination and that this effect is dependent on a functional nucleotide excision repair (NER) pathway. Transfection of COS cells carrying the dual supF vector with a purine-rich TFO, AG30, designed to bind as a third strand to a region between the two mutant supF genes yielded recombinants at a frequency of 0.37%, fivefold above background, whereas a scrambled sequence control oligomer was ineffective. In human cells deficient in the NER factor XPA, the ability of AG30 to induce recombination was eliminated, but it was restored in a corrected subline expressing the XPA cDNA. In comparison, the ability of triplex-directed psoralen cross-links to induce recombination was only partially reduced in XPA-deficient cells, suggesting that NER is not the only pathway that can metabolize targeted psoralen photoadducts into recombinagenic intermediates. Interestingly, the triplex-induced recombination was unaffected in cells deficient in DNA mismatch repair, challenging our previous model of a heteroduplex intermediate and supporting a model based on end joining. This work demonstrates that oligonucleotide-mediated triplex formation can be recombinagenic, providing the basis for a potential strategy to direct genome modification by using high-affinity DNA binding ligands.     

The stability of DNA triplexes inside cells as studied by iodine-125 radioprinting.

We studied the stability of a DNA triplex resulting from the binding of a 38 nt long purine motif triplex-forming oligonucleotide (TFO) to a covalently closed plasmid containing a target sequence from the human HPRT gene. Our in vitro experiments showed that the triplex formed at plasmid and TFO concentrations as low as 10(-9)M. Once formed, the triplex was remarkably stable and could withstand 10 min incubation at 65 degrees C. We next delivered these TFO-plasmid complexes into cultured human cells. To monitor the TFO-plasmid complexes inside cells we applied a new technique that we call 'radioprinting'. Because the TFO was(125)I labeled, we could quantitatively monitor the triplexes by measuring(125)I-induced DNA strand breaks in the target plasmid sequence. We found that the triplexes remain stable inside the cells for at least 48 h. Based on these findings we propose using TFO for indirect labeling of intact plasmid DNA. As a demonstration, we show that the intracellular distribution of a fluorescein-labeled TFO was different when it was liposome-delivered into cultured human cells alone or in a complex with the plasmid. In the latter case, the fluorescence was detected in nearly all the cells while detection of the plasmid by use of a marker gene (beta-galactosidase) revealed expression of the gene in only half of the cells.