Intermolecular triplex formation distorts the DNA duplex in the regulatory region of human papillomavirus type-11

Triplex technology in studies of DNA damage, DNA repair, and mutagenesis

Triplex-forming oligonucleotides (TFOs) can bind to the major groove of homopurine-homopyrimidine stretches of double-stranded DNA in a sequence-specific manner through Hoogsteen hydrogen bonding to form DNA triplexes. TFOs by themselves or conjugated to reactive molecules can be used to direct sequence-specific DNA damage, which in turn results in the induction of several DNA metabolic activities. Triplex technology is highly utilized as a tool to study gene regulation, molecular mechanisms of DNA repair, recombination, and mutagenesis. In addition, TFO targeting of specific genes has been exploited in the development of therapeutic strategies to modulate DNA structure and function. In this review, we discuss advances made in studies of DNA damage, DNA repair, recombination, and mutagenesis by using triplex technology to target specific DNA sequences.

Repair of DNA lesions associated with triplex-forming oligonucleotides

Triplex-forming oligonucleotides (TFOs) are gene targeting tools that can bind in the major groove of duplex DNA in a sequence-specific manner. When bound to DNA, TFOs can inhibit gene expression, can position DNA-reactive agents to specific locations in the genome, or can induce targeted mutagenesis and recombination. There is evidence that third strand binding, alone or with an associated cross-link, is recognized and metabolized by DNA repair factors, particularly the nucleotide excision repair pathway. This review examines the evidence for DNA repair of triplex-associated lesions.

Molecular dynamics simulation study of DNA triplex formed by mixed sequences in solution

The unrestrained molecular dynamics simulation of the triple helical DNA with mix sequences d(GACTGGTGAC).d(CTGACCACTG)*d (GACTGGTGAC), using the particle mesh Ewald sum, is presented here. The Ewald summation method effectively eliminates the usualcut-of of the long range interactions and allowed us to evaluate the full effect of the electrostatic forces. The AMBER5.0 force field has been used during the simulation in solvent. The MD results support a dynamically stable model of DNA triplex over the entire length of the trajectory. The duplex structure assumes the conformation, which is very close to B-DNA. In mixed sequences the purine bases occurs in both strand of DNA duplex. The bases of third strand do not favor the Hoogsteen or/and reverse Hoogsteen type of Hydrogen bonding but they form hydrogen bonds with the bases of both the strand of DNA duplex. The orientation of the third strand is parallel to one of the strand of duplex and all nucleotides (C, A, G & T) show isomorphic behavior with respect to the DNA duplex. The conformation of all the three strands is almost same except few exceptions. Due to interaction of third strand the conformational change in the duplex structure and a finite amount of displacement in the W-C base pairs have been observed. The conformational variation of the back bone torsion angles and helicoidal parameters, groove widths have been discussed. The sequence dependent effects on local conformation, helicoidal and morphological structure, width of the grooves of DNA helix may have important implication for understanding the functional energetics and specificity of interactions of DNA and its triplexes with proteins, pharmaceutical agents and other ligands.

Cloning and characterization of a novel caprine genomic repetitive element that hybridizes with papillomavirus DNA

A goat genomic library was screened by Southern blot hybridization at reduced stringency with a bovine papillomavirus type 5 (BPV 5) DNA probe in order to identify potential cellular and viral sequences related to the papillomavirus genome. A recombinant clone with an 8.5 kb genomic insert was found to contain a 1.3 kb PstI subfragment (designated as P1-1) that hybridized with the DNA of BPV 5, two murine papillomaviruses and human papillomavirus types 5 and 8, but not with DNA from another eight human and bovine papillomavirus types. Southern blot hybridization of the goat P1-1 DNA probe was restricted to a single 1.0 kb subfragment within the E1 open reading frame (ORF) of BPV 5 but produced multiple bands ranging between 1.0 and 9.0 kb when hybridized under stringent conditions with PstI-digested DNA obtained from different goat tissues. The genomic sequence of P1-1 has direct repeats of 10 and 13 nucleotides flanking 153 nucleotides, and 889 nucleotides of sequence, respectively, and an inverted repeat sequence of 11 nucleotides flanking a major ORF potentially coding for 244 residues. Potential splice acceptor and donor sites capable of joining with upstream and downstream exons are present within the major ORF. Sequence similarity between P1-1 and BPV 5 DNA at the nucleotide and amino acid level was limited to a stretch of 58 nucleotides which includes an oligopurine/pyrimidine tract. This region of similarity contains a predicted glutamic acid-rich domain. The P1-1 sequence is a novel repetitive element within the goat genome that is unrelated in sequence to papillomavirus DNA and to genomic sequences of mouse and man.

The GAA triplet-repeat expansion in Friedreich ataxia interferes with transcription and may be associated with an unusual DNA structure

Friedreich ataxia (FRDA), an autosomal recessive, neurodegenerative disease is the most common inherited ataxia. The vast majority of patients are homozygous for an abnormal expansion of a polymorphic GAA triplet repeat in the first intron of the X25 gene, which encodes a mitochondrial protein, frataxin. Cellular degeneration in FRDA may be caused by mitochondrial dysfunction, possibly due to abnormal iron accumulation, as observed in yeast cells deficient for a frataxin homologue. Using RNase protection assays, we have shown that patients homozygous for the expansion have a marked deficiency of mature X25 mRNA. The mechanism(s) by which the intronic GAA triplet expansion results in this reduction of X25 mRNA is presently unknown. No evidence was found for abnormal splicing of the expanded intron 1. Using cloned repeat sequences from FRDA patients, we show that the GAA repeat per se interferes with in vitro transcription in a length-dependent manner, with both prokaryotic and eukaryotic enzymes. This interference was most pronounced in the physiological orientation of transcription, when synthesis of the GAA-rich transcript was attempted. These results are consistent with the observed negative correlation between triplet-repeat length and the age at onset of disease. Using in vitro chemical probing strategies, we also show that the GAA triplet repeat adopts an unusual DNA structure, demonstrated by hyperreactivity to osmium tetroxide, hydroxylamine, and diethyl pyrocarbonate. These results raise the possibility that the GAA triplet-repeat expansion may result in an unusual yet stable DNA structure that interferes with transcription, ultimately leading to a cellular deficiency of frataxin.

Determination of 5' and 3' DNA triplex interference boundaries reveals the core DNA binding sequence for topoisomerase II

Previous studies have shown that formation of intermolecular DNA triplexes at sequences that overlap protein binding sites inhibits DNA binding by these proteins. We show that DNA cleavage by eukaryotic topoisomerase II is blocked by triplex formation at sites overlapping and adjacent to the triple binding site. To map precisely the boundaries of triplex interference, we constructed a vector containing enzyme binding sites of different lengths and flanked both 5' and 3' by DNA triplexes. We call this method Triplex Interference Mapping by Binding Element Replacement (TIMBER). Triplex regions within 3 bases 5' or 7 bases 3' of cleavage sites blocked DNA cleavage; triplex formation outside of this region had no effect upon cleavage activity. We conclude that topoisomerase II binding requires unhindered access to the major groove of a duplex DNA binding site in this 10-base region. In addition, the inclusion of topoisomerase II inhibitors yielded the same results for the triplex interference assays despite alterations in DNA cleavage site selection. The statistical analyses of over 500 topoisomerase II cleavage sites (in the presence or absence of inhibitors) suggest a model consistent with the region spanning -3 to +7 (relative to the cleavage site) containing most of the base-specific contacts for topoisomerase II. This triplex interference assay may prove valuable in the characterization of DNA binding sites for other proteins as well, particularly in conjunction with deletion analysis.

Structure and applications of intermolecular DNA triplexes

Current DNA binding drugs are not sequence specific. Triplex-forming oligonucleotides will bind targeted duplex DNA sites in a sequence-specific manner. A new class of DNA binding molecules based on triple-helical DNA formation promises a sequence-specific method of targeting discrete regions of DNA. DNA modifying molecules linked to third strands have been shown to modify only regions of DNA to which they were targeted. Current research will increase the understanding of triplex DNA structure and will lead to improved DNA binding drugs.