Structural polymorphism of homopurine--homopyrimidine sequences: the secondary DNA structure adopted by a d(GA.CT)22 sequence in the presence of zinc ions.

In this paper, we have analysed the conformational behaviour shown by the homopurine--homopyrimidine alternating d(GA.CT)22 sequence cloned into SV40. Our results show that, in the presence of zinc ions, the d(GA.CT)22 sequence adopts an altered secondary DNA structure (*H-DNA) which differs from either B-DNA or H-DNA. Formation of *H-DNA is facilitated by negative supercoiling and does not appear to require base protonation, since it is induced at neutral pH by approximately 0.4 mM ZnCl2. The patterns of OsO4 and DEPC modification obtained in the presence of zinc are compatible with a homopurine--homopurine--homopyridimine triplex, though other structural models for *H-DNA are also possible. The hypersensitivity to S1-cleavage of the d(GA.CT)22 sequence is reinterpreted in terms of the equilibria between the B-, H- and *H-forms of the sequence. These results reveal the high degree of structural polymorphism shown by homopurine-homopyrimidine sequences. Its biological relevance is discussed.     

DHX9 helicase is involved in preventing genomic instability induced by alternatively structured DNA in human cells

Sequences that have the capacity to adopt alternative (i.e. non-B) DNA structures in the human genome have been implicated in stimulating genomic instability. Previously, we found that a naturally occurring intra-molecular triplex (H-DNA) caused genetic instability in mammals largely in the form of DNA double-strand breaks. Thus, it is of interest to determine the mechanism(s) involved in processing H-DNA. Recently, we demonstrated that human DHX9 helicase preferentially unwinds inter-molecular triplex DNA in vitro. Herein, we used a mutation-reporter system containing H-DNA to examine the relevance of DHX9 activity on naturally occurring H-DNA structures in human cells. We found that H-DNA significantly increased mutagenesis in small-interfering siRNA-treated, DHX9-depleted cells, affecting mostly deletions. Moreover, DHX9 associated with H-DNA in the context of supercoiled plasmids. To further investigate the role of DHX9 in the recognition/processing of H-DNA, we performed binding assays in vitro and chromatin immunoprecipitation assays in U2OS cells. DHX9 recognized H-DNA, as evidenced by its binding to the H-DNA structure and enrichment at the H-DNA region compared with a control region in human cells. These composite data implicate DHX9 in processing H-DNA structures in vivo and support its role in the overall maintenance of genomic stability at sites of alternatively structured DNA.     

Length-dependent structure formation in Friedreich ataxia (GAA)n*(TTC)n repeats at neutral pH

More than 15 human genetic diseases have been associated with the expansion of trinucleotide DNA repeats, which may involve the formation of non-duplex DNA structures. The slipped-strand nucleation of duplex DNA within GC-rich trinucleotide repeats may result in the changes of repeat length; however, such a mechanism seems less likely for the AT-rich (GAA)_n·(TTC)_n repeats. Using two-dimensional agarose gels, chemical probing and atomic force microscopy, we characterized the formation of non-B-DNA structures in the Friedreich ataxia-associated (GAA)_n·(TTC)_n repeats from the FRDA gene that were cloned with flanking genomic sequences into plasmids. For the normal genomic repeat length (n = 9) our data are consistent with the formation of a very stable protonated intramolecular triplex (H-DNA). Its stability at pH 7.4 is likely due to the high proportion of the T·A·T triads which form within the repeats as well as in the immediately adjacent AT-rich sequences with a homopurine· homopyrimidine bias. At the long normal repeat length (n = 23), a family of H-DNAs of slightly different sizes has been detected. At the premutation repeat length (n = 42) and higher negative supercoiling, the formation of a single H-DNA structure becomes less favorable and the data are consistent with the formation of a bi-triplex structure.     

Kinetic trapping of H-DNA by oligonucleotide binding.

Homopurine-homopyrimidine mirror repeats are known to adopt the H form under acidic pH and/or negative supercoiling. In H-DNA, one half of the purine strand enters the triplex whereas the second half is unstructured and can form duplex with complementary oligonucleotide. However, because the same oligonucleotide can form triplex with the homopurine-homopyrimidine insert, one could expect that oligonucleotide would make H-DNA thermodynamically less favorable, as was claimed by Lyamichev et al. Nucl. Acids Res. 16, 2165-2178 (1988). Now we show that complex between oligonucleotide and H-DNA, formed under conditions favorable for the H-form extrusion, is kinetically trapped in superhelical DNA and remains stable up much higher pH values than H-DNA alone. Experiments on chemical probing show that such complex exists for a plasmid with native superhelical density at pH7. We have also used this approach to demonstrate a pH-dependent structural transition in yeast telomeric sequence, d(CACACCCA)16.     

The effect of zinc on the secondary structure of d(GA.TC)n DNA sequences of different length: a model for the formation *H-DNA.

Alternating d(GA.TC)n DNA sequences are known to undergo transition to *H-DNA in the presence of zinc. Here, the effect of zinc on the secondary DNA structure of d(GA.TC)n sequences of different length (n = 5, 8, 10 and 19) was determined. Short d(GA.TC)n sequences form *H-DNA with a higher difficulty than longer ones. At bacterial negative superhelical density (- sigma = 0.05), zinc still induces transition to the *H-DNA conformation at a d(GA.TC)10 sequence but shorter sequences do not form *H-DNA. Transition to *H-DNA at a d(GA.TC)8 sequence is observed under conditions which destabilize the DNA double helix such as high negative supercoiling or low ionic strength. Our results indicate that a first step in the transition to *H-DNA is the formation of a denaturation bubble at the centre of the repeated DNA sequence, suggesting that the primary role of zinc is to induce a local denaturation of the DNA double helix. Subsequently, zinc might also participate in the stabilization of the altered DNA conformation through its direct interaction with the bases. Based on these results a model for the formation of *H-DNA is proposed.     

Stabilities of intrastrand pyrimidine motif DNA and RNA triple helices

Nucleic acid triple helices have provoked interest since their discovery more than 40 years ago, but it remains unknown whether such structures occur naturally in cells. To pursue this question, it is important to determine the stabilities of representative triple helices at physiological temperature and pH. Previous investigations have concluded that while both DNA and RNA can participate in the pyrimidine triplex motif under mildly acidic conditions, these structures are often relatively unstable at neutral pH. We are now explorin g the stability of intrastrand DNA and RNA pyrimidine motif triplexes at physiological temperature and pH. Duplex and triplex formation were monitored by thermal denaturation analysis, circular dichroism spectroscopy and gel shift experiments. Short intrastrand triplexes were observed to form in the pyrimidine motif in both DNA and RNA. In the presence of physiological concentrations of Mg²⁺ and at physiological pH, all detected triplexes were sufficiently stable to persist at physiological temperature. If sequences specifying such intrastrand triplexes are encoded in genomes, the potential exists for the formation of stable structures in RNA or DNA in vivo.     

Synthesis of novel poly(dG)-poly(dG)-poly(dC) triplex structure by Klenow exo- fragment of DNA polymerase I

The extension of the G-strand of long (700 bp) poly(dG)–poly(dC) by the Klenow exo⁻ fragment of DNA polymerase I yields a complete triplex structure of the H-DNA type. High-performance liquid chromatography analysis demonstrates that the length of the G-strand is doubled during the polymerase synthesis. Fluorescence resonance energy transfer analysis shows that the 5′ ends of the G- and the C-strands, labeled with fluorescein and TAMRA, respectively, are positioned close to each other in the product of the synthesis. Atomic force microscopy morphology imaging shows that the synthesized structures lack single-stranded fragments and have approximately the same length as the parent 700 bp poly(dG)–poly(dC). CD spectrum of the polymer has a large negative peak at 278 nm, which is characteristic of the poly(dG)–poly(dG)–poly(dC) triplex. The polymer is resistant to DNase and interacts much more weakly with ethidium bromide as compared with the double-stranded DNA.