Influence of DNA sequence on the formation of non-B right-handed helices in oligopurine.oligopyrimidine inserts in plasmids

Detection of alternative DNA structures and its implications for human disease

Around 3% of the genome consists of simple DNA repeats that are prone to forming alternative (non-B) DNA structures, such as hairpins, cruciforms, triplexes (H-DNA), four-stranded guanine quadruplexes (G4-DNA), and others, as well as composite RNA:DNA structures (e.g., R-loops, G-loops, and H-loops). These DNA structures are dynamic and favored by the unwinding of duplex DNA. For many years, the association of alternative DNA structures with genome function was limited by the lack of methods to detect them in vivo. Here, we review the recent advancements in the field and present state-of-the-art technologies and methods to study alternative DNA structures. We discuss the limitations of these methods as well as how they are beginning to provide insights into causal relationships between alternative DNA structures, genome function and stability, and human disease.

Direct observation of one-dimensional plasmon coupling in metallic nanofibers prepared by evaporation-induced self-assembly with DNA

Here we report a simple method for the preparation of highly aligned metallic nanofibers with anisotropic aggregates of silver nanoparticles (AgNPs) as well as a direct observation of localized plasmon field and its coupling in the prepared metallic nanofibers. Metallic nanofibers of several tens of nanometers wide and millimeters long were prepared. The preparation method, which is based on the process of evaporation-induced self-assembly with DNA and drying front movement, eliminates the need for lithography and an external field, and it is fast, cheap and easy. Dark-field scattering spectroscopy was used to study the strong plasmon coupling of AgNPs in the metallic nanofibers. We observed strong near-field coupling between neighboring nanoparticles, which results in red-shifted multipolar plasmon modes that are highly polarized along the fiber axis. The polarization dependence of plasmon coupling in the metallic nanofibers observed in this study was satisfactorily explained by the morphology of the metallic nanofibers, which was characterized by atomic force microscopy (AFM) and scanning electron microscopy (SEM). Furthermore, Raman spectra imaging of the metallic nanofibers revealed the existence of intense hot spots localized along their axes, which played a significant role in the intensity of surface enhanced Raman scattering (SERS) signals from DNA bases in the metallic nanofiber. Our results demonstrate the use of evaporation-induced self-assembly with DNA as a straightforward method to produce one-dimensional coupling of localized plasmons with a longer scale.

pH Sensitive DNA Devices

The physicochemical properties of small molecules as well as macromolecules are modulated by solution pH, and DNA is no exception. Special sequences of DNA can adopt unusual conformations e.g., triplex, i-motif and A-motif, depending on solution pH. The specific range of pH for these unusual structures is dictated by the pKa of protonation of the relevant nucleobase involved in the resultant non-canonical base pairing that is required to stabilise the structure. The biological significance of these pH-dependent structures is not yet clear. However, these non-B-DNA structures have been used to design different devices to direct chemical reactions, generate mechanical force, sense pH, etc. The performance of these devices can be monitored by a photonic signal. They are autonomous and their ‘waste free’ operation cycles makes them highly processive. Applications of these devices help to increase understanding of the structural polymorphism of the motifs themselves. The design of these devices has continuously evolved to improve their performance efficiency in different contexts. In some examples, these devices have been shown to perform inside complex living systems with similar efficiencies, to report on the chemical environment there. The robust performance of these devices opens up exciting possibilities for pH-sensitive DNA devices in the study of various pH-regulated biological events.

Thymine dimer-induced structural changes to the DNA duplex examined with reactive probes (†)

Despite significant progress in the past decade, questions still remain about the complete structural, dynamic, and thermodynamic effect of the cis-syn cyclobutane pyrimidine dimer lesion (hereafter called the thymine dimer) on double-stranded genomic DNA. We examined a 19-mer oligodeoxynucleotide duplex containing a thymine dimer lesion using several small, base-selective reactive chemical probes. These molecules probe whether the presence of the dimer causes the base pairs to be more accessible to the solution, either globally or adjacent to the dimer. Though all of the probes confirm that the overall structure of the dimer-containing duplex is conserved compared to that of the undamaged parent duplex, reactions with both diethyl pyrocarbonate and Rh(bpy)(2)(chrysi)(3+) indicate that the duplex is locally destabilized near the lesion. Reactions with potassium permanganate and DEPC hint that the dimer-containing duplex may also be globally more accessible to the solution through a subtle shift in the double-stranded DNA ↔ single-stranded DNA equilibrium. To begin to distinguish between kinetic and thermodynamic effects, we determined the helix melting thermodynamic parameters for the dimer-containing and undamaged parent duplexes by microcalorimetry and UV melting. The presence of the thymine dimer causes this DNA duplex to be slightly less stable enthalpically but slightly less unstable entropically at 298 K, causing the overall free energy of duplex melting to remain unchanged by the dimer lesion within the error of the experiment. Here we consider these results in the context of what has been learned about the thymine dimer lesion from NMR, X-ray crystallographic, and molecular biological methods.

Quadruplex formation is necessary for stable PNA invasion into duplex DNA of BCL2 promoter region

Guanine-rich sequences are highly abundant in the human genome, especially in regulatory regions. Because guanine-rich sequences have the unique ability to form G-quadruplexes, these structures may play a role in the regulation of gene transcription. In previous studies, we demonstrated that formation of G-quadruplexes could be induced with peptide nucleic acids (PNAs). PNAs designed to bind the C-rich strand upstream of the human BCL2 gene promoted quadruplex formation in the complementary G-rich strand. However, the question whether G-quadruplex formation was essential for PNA invasion remained unanswered. In this study, we compared PNA invasion in the native and mutant, i.e. not forming G-quadruplex, BCL2 sequences and showed that G-quadruplex is required for effective PNA invasion into duplex DNA. This finding provides strong evidence for not only sequence-specific, but also quadruplex specific, gene targeting with PNA probes. In addition, we examined DNA-duplex invasion potential of PNAs of various charges. Using the gel shift assay, chemical probing and dimethyl sulfate (DMS) protection studies, we determined that uncharged zwitterionic PNA has the highest binding specificity while preserving efficient duplex invasion.

Atomic force microscopy and surface-enhanced Raman scattering detection of DNA based on DNA-nanoparticle complexes

We report a simple method for the label-free detection of double-stranded DNA using surface-enhanced Raman scattering (SERS). We prepared cetyltrimethylammonium bromide (CTAB)-capped silver nanoparticles and a DNA-nanoparticle complex by adding silver nanoparticles to lambda-DNA solutions. In the present study, the utilization of CTAB-capped silver nanoparticles facilitates the electrostatic interaction between DNA molecules and silver nanoparticles; at the same time, the introduction of DNA avoids adding aggregating agent for the formation of nanoparticle aggregates to obtain large enhancement of DNA, because the DNA acts as both the probe molecules and aggregating agent of Ag nanoparticles. Atomic force microscopy (AFM) studies show that the morphology of DNA-Ag nanoparticle complexes seems to be determined by the concentrations of the DNA and the nanoparticles. Surface-enhanced Raman scattering (SERS) studies show that the morphology of the complexes plays a significant role in the intensity of SERS signals of DNA, and the best signal enhancement of DNA can be obtained by fine-tuning the experimental parameters. The SERS spectrum affords important structural information about the bases, phosphate backbone, and the conformation of DNA after mixing the DNA solutions with the Ag sol.

Molecular aspects on the interaction of protoberberine, benzophenanthridine, and aristolochia group of alkaloids with nucleic acid structures and biological perspectives

Alkaloids occupy an important position in chemistry and pharmacology. Among the various alkaloids, berberine and coralyne of the protoberberine group, sanguinarine of the benzophenanthridine group, and aristololactam-beta-d-glucoside of the aristolochia group have potential to form molecular complexes with nucleic acid structures and have attracted recent attention for their prospective clinical and pharmacological utility. This review highlights (i) the physicochemical properties of these alkaloids under various environmental conditions, (ii) the structure and functional aspects of various forms of deoxyribonucleic acid (DNA) (B-form, Z-form, H(L)-form, protonated form, and triple helical form) and ribonucleic acid (RNA) (A-form, protonated form, and triple helical form), and (iii) the interaction of these alkaloids with various polymorphic DNA and RNA structures reported by several research groups employing various analytical techniques like absorbance, fluorescence, circular dichroism, and NMR spectroscopy; electrospray ionization mass spectrometry, thermal melting, viscosity, and DNase footprinting as well as molecular modeling and thermodynamic studies to provide detailed binding mechanism at the molecular level for structure-activity relationship. Nucleic acids binding properties of these alkaloids are interpreted in relation to their biological activity.

Association of poly-purine/poly-pyrimidine sequences with meiotic recombination hot spots

Background

Meiotic recombination events have been found to concentrate in 1–2.5 kilo base regions, but these recombination hot spots do not share a consensus sequence and why they occur at specific sites is not fully understood. Some previous evidence suggests that poly-purine/poly-pyrimidine (poly-pu/py) tracts (PPTs), a class of sequence with distinctive biochemical properties, could be involved in recombination, but no general association of PPTs with meiotic recombination hot spots has previously been reported.

Results

We used computational methods to investigate in detail the relationship between PPTs and hot spots. We show statistical associations of PPT frequency with hot spots of meiotic recombination initiating lesions, double-strand breaks, in the genome of the yeast S. cerevisiae and with experimentally well characterized human meiotic recombination hot spots. Supporting a possible role of poly-pu/py-rich sequences in hot spot recombination, we also found that all three single nucleotide polymorphisms previously shown to be associated with human hot spot activity changes occur within sequence contexts of 14 bp or longer that are 85% or more poly-pu/py and at least 70% G/C. These polymorphisms are all close to the hot spot mid points. Comparing the sequences of experimentally characterized human hot spots with the orthologous regions of the chimpanzee genome previously shown not to contain hot spots, we found that in all five cases in which comparisons for the hot spot central regions are possible with publicly available sequence data, there are differences near the human hot spot mid points within sequences 14 bp or longer consisting of more than 80% poly-pu/py and at least 50% G/C.

Conclusion

Our results, along with previous evidence for the unique biochemical properties and recombination-stimulating potential of poly-pu/py-rich sequences, suggest that the possible functional involvement of this type of sequence in meiotic recombination hot spots deserves further experimental exploration.

Analysis of Non‐B DNA Structure at Chromosomal Sites in the Mammalian Genome

Changes at sites of genetic instability ultimately involve DNA repair pathways. Some sites of genetic instability in the mammalian genome appear to be unstable because they adopt a non-B DNA conformation. We describe two structural approaches for determination of whether a genomic region is configured in a non-B DNA conformation. Our studies indicate that at least some chromosomal fragile sites can be explained by such altered DNA conformations. One of the methods that we describe is called the bisulfite modification assay. This is a powerful assay because it provides information on individual DNA molecules. The second approach uses preexisting DNA structural reagents, but describes our specific application of them to analysis of DNA in vivo.

Evidence for a Triplex DNA Conformation at the bcl-2 Major Breakpoint Region of the t(14;18) Translocation

The most common chromosomal translocation in cancer, t(14;18), occurs at the bcl-2 major breakpoint region (Mbr) in follicular lymphomas. The 150-bp bcl-2 Mbr, which contains three breakage hotspots (peaks), has a single-stranded character and, hence, a non-B DNA conformation both in vivo and in vitro. Here, we use gel assays and electron microscopy to show that a triplex-specific antibody binds to the bcl-2 Mbr in vitro. Bisulfite reactivity shows that the non-B DNA structure is favored by, but not dependent upon, supercoiling and suggests a possible triplex conformation at one portion of the Mbr (peak I). We have used circular dichroism to test whether the predicted third strand of that suggested structure can indeed form a triplex with the duplex at peak I, and it does so with 1:1 stoichiometry. Using an intracellular minichromosomal assay, we show that the non-B DNA structure formation is critical for the breakage at the bcl-2 Mbr, because a 3-bp mutation that disrupts the putative peak I triplex also markedly reduces the recombination of the Mbr. A three-dimensional model of such a triplex is consistent with bond length, bond angle, and energetic restrictions (stacking and hydrogen bonding). We infer that an imperfect purine/purine/pyrimidine (R.R.Y) triplex likely forms at the bcl-2 Mbr in vitro, and in vivo recombination data favor this as the major DNA conformation in vivo as well.

Raman microspectroscopic study of effects of Na(I) and Mg(II) ions on low pH induced DNA structural changes

In this work a confocal Raman microspectrometer is used to investigate the influence of Na(+) and Mg(2+) ions on the DNA structural changes induced by low pH. Measurements are carried out on calf thymus DNA at neutral pH (7) and pH 3 in the presence of low and high concentrations of Na(+) and Mg(2+) ions, respectively. It is found that low concentrations of Na(+) ions do not protect DNA against binding of H(+). High concentrations of monovalent ions can prevent protonation of the DNA double helix. Our Raman spectra show that low concentrations of Mg(2+) ions partly protect DNA against protonation of cytosine (line at 1262 cm(-1)) but do not protect adenine and guanine N(7) against binding of H(+) (characteristic lines at 1304 and 1488 cm(-1), respectively). High concentrations of Mg(2+) can prevent protonation of cytosine and protonation of adenine (disruption of AT pairs). By analyzing the line at 1488 cm(-1), which obtains most of its intensity from a guanine vibration, high magnesium salt protect the N(7) of guanine against protonation. A high salt concentration can prevent protonation of guanine, cytosine, and adenine in DNA. Higher salt concentrations cause less DNA protonation than lower salt concentrations. Magnesium ions are found to be more effective in protecting DNA against binding of H(+) as compared with calcium ions presented in a previous study. Divalent metal cations (Mg(2+), Ca(2+)) are more effective in protecting DNA against protonation than monovalent ions (Na(+)).

Numerical simulations of Raman spectra of guanine-cytosine Watson-Crick and protonated Hoogsteen base pairs

Large changes in the Raman spectra of calf thymus DNA are observed upon lowering the pH. In order to gain a better insight into these effects, several simulations of the Raman spectra of the guanine-cytosine (GC) Watson-Crick and Hoogsteen base pairs are performed. By comparing the Raman bands of GC base pairs in calf thymus DNA at high and low pH with the theoretical simulations of GC base pairs, it is found that the intensity changes in the theoretical bands located between 400 and 1000 cm(-1) are small compared to the experimental ones. The behavior of the cytosine band at 1257 cm(-1) upon lowering the pH is not reproduced in the GC theoretical spectra. The bands located above 1300 cm(-1) in the theoretical spectra display intensity changes that are similar to those found for GC base pairs in calf thymus DNA spectra.

Sticky DNA, a long GAA.GAA.TTC triplex that is formed intramolecularly, in the sequence of intron 1 of the frataxin gene

Friedreich's ataxia is caused by the massive expansion of GAA.TTC repeats in intron 1 of the frataxin (X25) gene. Our prior investigations showed that long GAA.TTC repeats formed very stable triplex structures which caused two repeat tracts to adhere to each other (sticky DNA). This process was dependent on negative supercoiling and the presence of divalent metal ions. Herein, we have investigated the formation of sticky DNA from plasmid monomers and dimers; sticky DNA is formed only when two tracts of sufficiently long (GAA.TTC)(n) (n = 59-270) are present in a single plasmid DNA and are in the direct repeat orientation. If the inserts are in the indirect (inverted) repeat orientation, no sticky DNA was observed. Furthermore, kinetic studies support the intramolecular nature of sticky DNA formation. Electron microscopy investigations also provide strong data for sticky DNA as a single long triplex. Hence, these results give new insights into our understanding of the capacity of sticky DNA to inhibit transcription and thereby reduce the level of frataxin protein as related to the etiology of Friedreich's ataxia.

Origin and instability of GAA repeats: insights from Alu elements

Expansion of GAA repeats in the intron of the frataxin gene is involved in the autosomal recessive Friedreich's ataxia (FRDA). The GAA repeats arise from a stretch of adenine residues of an Alu element. These repeats have a size ranging from 7- 38 in the normal population, and expand to thousands in the affected individuals. The mechanism of origin of GAA repeats, their polymorphism and stability are not well understood. In this study, we have carried out an extensive analysis of GAA repeats at several loci in the humans. This analysis indicates the association of a majority of GAA repeats with the 3' end of an "A" stretch present in the Alu repeats. Further, the prevalence of GAA repeats correlates with the evolutionary age of Alu subfamilies as well as with their relative frequency in the genome. Our study on GAA repeat polymorphism at some loci in the normal population reveals that the length of the GAA repeats is determined by the relative length of the flanking A stretch. Based on these observations, a possible mechanism for origin of GAA repeats and modulatory effects of flanking sequences on repeat instability mediated by DNA triplex is proposed.

Mutation rate and specificity analysis of tetranucleotide microsatellite DNA alleles in somatic human cells

We have systematically varied microsatellite sequence composition to determine the effects of repeat unit size, G+C content, and DNA secondary structure on microsatellite stability in human cells. The microsatellites were inserted in frame within the 5' region of the herpes simplex virus thymidine kinase (HSV-tk) gene. The polypyrimidine/polypurine microsatellites displayed enhanced S1 nuclease sensitivity in vitro, consistent with the formation of non-B-form DNA structures. Microsatellite mutagenesis studies were performed with a shuttle vector system in which inactivating HSV-tk mutations are measured after replication in a nontumorigenic cell line. A significant increase in the HSV-tk mutation frequency per cell generation was observed after insertion of [TTCC/AAGG]9, [TTTC/AAAG]9, or [TCTA/AGAT]9 sequences (P <or= 0.0002), relative to the HSV-tk gene control. We observed that the G + C content of the microsatellite may affect mutagenesis, as the mean microsatellite mutation rates of the [TTTC/AAAG]9 and [TCTA/AGAT]9 alleles were sevenfold and 11-fold higher, respectively, than the [TTCC/AAGG]9 allele. A bias toward expansion mutations was noted for the majority of clones bearing the [TTCC/AAGG]9 allele as well as a [TC/AG]17 microsatellite of similar allele length. The mean microsatellite mutation rate of the [TTCC/AAGG]9 allele did not differ significantly from that for a [TC/AG]11 allele, demonstrating that these tetranucleotide and dinucleotide alleles are of equivalent stability. It is known that microsatellite mutagenesis is affected by the number of repeat units within an allele. Our data suggest that additional biochemical factors may regulate both the rate and specificity of somatic cell microsatellite mutagenesis.

Transcription termination factor TTF-I exhibits contrahelicase activity during DNA replication

In mammals, sequence-specific termination of DNA replication within the ribosomal RNA genes is catalyzed by a defined DNA-protein complex that includes transcription termination factor I (TTF-I). Here we show that TTF-I acts as a polar contrahelicase contrary to the intrinsic 3' -->5' helicase activity of SV40 large T antigen. The contrahelicase activity requires binding of TTF-I to its cognate recognition site and the presence of an auxiliary GC-rich sequence, which is able to form a specific secondary structure. Mutations in the GC-rich sequence lead to a loss of folding into correct secondary structure and abrogate contrahelicase activity. The finding suggests that a specific interaction between the Sal box-bound TTF-I and the GC-rich sequence is essential for the inhibition of T antigen helicase. Analyses of N-terminally truncated mutants of TTF-I showed inhibition of helicase by the same domain of TTF-I, which is also responsible for replication fork arrest.

GGA*TCC-interrupted triplets in long GAA*TTC repeats inhibit the formation of triplex and sticky DNA structures, alleviate transcription inhibition, and reduce genetic instabilities

Large expansions of GAA.TTC repeats in the first intron of the frataxin (X25) gene are the principal mutation responsible for Friedreich's ataxia (FRDA). Sticky DNA, based on R.R.Y triplexes, was found at the expanded GAA.TTC repeats from FRDA patients. The (GAAGGA.TCCTTC)(65) repeat occurs in the same frataxin locus but is nonpathogenic and does not form sticky DNA. To elucidate the behavior of sticky DNA, we introduced various extents of GGA.TCC interruptions into the long GAA.TTC repeat. More than 20% of GGA.TCC interruptions abolished the formation of sticky DNA. However, the GAA.TTC repeats with less than 11% of GGA.TCC interruptions formed triplexes and/or sticky DNA similar to the uninterrupted repeat sequence. These triplexes showed different P1 nuclease sensitivities, and the GGA.TCC interruptions were slightly more sensitive than the surrounding GAA.TTC repeats. Furthermore, genetic instability investigations in Escherichia coli revealed that a small number (4%) of interruptions substantially stabilized the long GAA.TTC tracts. Furthermore, the greater the extent of interruptions of the GAA.TTC repeats, the less inhibition of in vitro transcription was observed, as expected, based on the capacity of interruptions to inhibit the formation of sticky DNA. We propose that the interruptions introduce base mismatches into the R.R.Y triplex, which explains the observed chemical and biological properties.

Pkd1 unusual DNA conformations are recognized by nucleotide excision repair

The 2.5-kilobase pair poly(purine.pyrimidine) (poly(R.Y)) tract present in intron 21 of the polycystic kidney disease 1 (PKD1) gene has been proposed to contribute to the high mutation frequency of the gene. To evaluate this hypothesis, we investigated the growth rates of 11 Escherichia coli strains, with mutations in the nucleotide excision repair, SOS, and topoisomerase I and/or gyrase genes, harboring plasmids containing the full-length tract, six 5'-truncations of the tract, and a control plasmid (pSPL3). The full-length poly(R.Y) tract induced dramatic losses of cell viability during the first few hours of growth and lengthened the doubling times of the populations in strains with an inducible SOS response. The extent of cell loss was correlated with the length of the poly(R.Y) tract and the levels of negative supercoiling as modulated by the genotype of the strains or drugs that specifically inhibited DNA gyrase or bound to DNA directly, thereby affecting conformations at specific loci. We conclude that the unusual DNA conformations formed by the PKD1 poly(R.Y) tract under the influence of negative supercoiling induced the SOS response pathway, and they were recognized as lesions by the nucleotide excision repair system and were cleaved, causing delays in cell division and loss of the plasmid. These data support a role for this sequence in the mutation of the PKD1 gene by stimulating repair and/or recombination functions.

Evidence for a DNA triplex in a recombination-like motif: I. Recognition of Watson-Crick base pairs by natural bases in a high-stability triplex

Data are presented on a triplex type with two parallel homologous strands for which triplex formation is almost as strong as duplex formation at least for some sequences and even at pH 7 and 0.2 M NaCl. The evidence mainly rests upon comparing thermodynamic properties of similar systems. A paperclip oligonucleotide d(A12C4T12C4A12) with two linkers C4 obviously can form a triplex with parallel back-folded adenine strand regions, because the single melting transition of this complex splits in two transitions by introducing mismatches only in the third strand region. Respectively, a hairpin duplex d(A12C4T12) and a single strand d(A12) form a triplex as a 1:1 complex in which the second adenine strand is parallel oriented to the homologous one in the Watson-Crick paired duplex. In this system the melting temperature T(m) of the triplex is practically the same as that of the duplex d(A12)-d(T12), at least within a complex concentration range of 0.2-4.0 microM. The melting behaviour of complexes between triplex stabilizing ligand BePI and the system hairpin duplex plus single strand supports the triplex model. Non-denaturing gel electrophoresis suggests the existence of a triplex for a system in which five of the twelve A-T*A base triads are substituted by C-G*C base triads. The recognition between any substituted Watson-Crick base pair (X-Y) in the hairpin duplex d(A4XA7C4T7YT4) and the correspondingly replaced base (Z) in the third strand d(A4ZA7) is mutually selective. All triplexes with matching base substitutions (Z = X) have nearly the same stability (T(m) values from 29 to 33.5 degrees C), whereas triplexes with non-matching substitutions (Z not equal X) show a clearly reduced stability (T(m) values from 15 to 22 degrees C) at 2microM equimolar oligonucleotide concentration. Most nucleic acid triple helices hitherto known are limited to homopurine-homopyrimidine sequences in the target duplex. A stable triplex formation is demonstrated for inhomogeneous sequences tolerating at least 50% pyrimidine content in the homologous strands. On the basis of the surprisingly similar thermodynamic parameters for duplex and triplex, and of the fact that this triplex type seems to be more stable than many other natural DNA triplexes known, and on the basis of semiempirical and molecule mechanical calculations, we postulate bridging interactions of the third strand with the two other strands in the triplex according to the recombination motif. This triplex, denoted by us 'recombination-like form', tolerates heterogeneous base sequences.

In vitro and in vivo ligation-mediated polymerase chain reaction analysis of a polypurine/polypyrimidine sequence upstream of the mouse metallothionein-I gene

The mouse metallothionein-I homopurine/homopyrimidine (MT-I R/Y) sequence is a 128-base pair element located approximately 1.2 kilobase pairs upstream of the MT-I gene. Previous in vitro studies of this sequence in purified plasmids indicated the formation of a non-B DNA structure stabilized by acidic pH and negative supercoiling. We now present a detailed in vitro and in vivo analysis of the MT-I R/Y sequence using chemical probes of DNA structure and ligation-mediated polymerase chain reaction. In vivo analysis suggests neither profound base unpairing nor protein binding within the MT-I R/Y sequence before or after metal induction of MT-I. We conclude for this element that the propensity to adopt an unusual DNA structure in vitro does not imply the occurrence of such a structure in vivo. We were able to show both in purified genomic DNA and in vivo that only isolated thymines and the 3' terminal thymine in strings of consecutive thymines are modified significantly by KMnO(4), indicating an altered thymine accessibility pattern within the R/Y sequence. This KMnO(4) reactivity pattern is more consistent and predictable within the R/Y sequence when compared with flanking sequences. We propose a simple steric interference model to explain the observed pattern of KMnO(4) modification of thymines.

Unexpected formation of parallel duplex in GAA and TTC trinucleotide repeats of Friedreich's ataxia

The onset and progress of Friedreich's ataxia (FRDA) is associated with the genetic instability of the (GAA).(TTC) trinucleotide repeats located within the frataxin gene. The instability of these repeats may involve the formation of an alternative DNA structure. Poly-purine (R)/poly-pyrimidine (Y) sequences typically form triplex DNA structures which may contribute to genetic instability. Conventional wisdom suggested that triplex structures formed by these poly-purine (R)/poly-pyrimidine (Y) sequences may contribute to their genetic instability. Here, we report the characterization of the single-stranded GAA and TTC sequences and their mixtures using NMR, UV-melting, and gel electrophoresis, as well as chemical and enzymatic probing methods. We show that the FRDA GAA/TTC, repeats are capable of forming various alternative structures. The most intriguing is the observation of a parallel (GAA).(TTC) duplex in equilibrium with the antiparallel Watson-Crick (GAA).(TTC) duplex. We also show that the GAA strands form self-assembled structures, whereas the TTC strands are essentially unstructured. Finally, we demonstrate that the FRDA repeats form only the YRY triplex (but not the RRY triplex) at neutral pH and the complete formation of the YRY triplex requires the ratio of GAA to TTC strand larger than 1:2. The structural features presented here and in other studies distinguish the FRDA (GAA)¿(TTC) repeats from the fragile X (CGG).CCG), myotonic dystrophy (CTG).(CAG) and the Huntington (CAG).(CTG) repeats.

Sticky DNA: self-association properties of long GAA.TTC repeats in R.R.Y triplex structures from Friedreich's ataxia

A novel DNA structure, sticky DNA, is described for lengths of (GAA.TTC)n found in intron 1 of the frataxin gene of Friedreich's ataxia patients. Sticky DNA is formed by the association of two purine.purine.pyrimidine (R.R.Y) triplexes in negatively supercoiled plasmids at neutral pH. An excellent correlation was found between the lengths of (GAA.TTC) (> 59 repeats): first, in FRDA patients, second, required to inhibit transcription in vivo and in vitro, and third, required to adopt the sticky conformation. Fourth, (GAAGGA.TCCTTC)65, also found in intron 1, does not form sticky DNA, inhibit transcription, or associate with the disease. Hence, R.R.Y triplexes and/or sticky DNA may be involved in the etiology of FRDA.

Triple helix formation: binding avidity of acridine-conjugated AG motif third strands containing natural, modified and surrogate bases opposed to pyrimidine interruptions in a polypurine target

A critical issue for the general application of triple-helix-forming oligonucleotides (TFOs) as modulators of gene expression is the dramatically reduced binding of short TFOs to targets that contain one or two pyrimidines within an otherwise homopurine sequence. Such targets are often found in gene regulatory regions, which represent desirable sites for triple helix formation. Using intercalator-conjugated AG motif TFOs, we compared the efficacy and base selectivity of 13 different bases or base surrogates in opposition to pyrimidines and purines substituted into selected positions within a paradigm 15-base polypurine target sequence. We found that substitutions closer to the intercalator end of the TFO (positions 4-6) had a more deleterious effect on the dissociation constant (K d) than those farther away (position 11). Opposite T residues at position 11, 3-nitropyrrole or cytosine in the TFO provided adequate binding avidity for useful triplex formation (K ds of 55 and 110 nM, respectively). However, 3-nitropyrrole was more base selective than cytosine, binding to T >/=4 times better than to A, G or C. None of the TFOs tested showed avid binding when C residues were in position 11, although the 3-nitropyrrole-containing TFO bound with a K d of 200 nM, significantly better than the other designs. Molecular modeling showed that the 3-nitropyrrole.T:A triad is isomorphous with the A.A:T triad, and suggests novel parameters for evaluating new base triad designs.

Cruciform-extruding regulatory element controls cell-specific activity of the tyrosine hydroxylase gene promoter

Tyrosine hydroxylase (TH) is expressed specifically in catecholaminergic cells. We have identified a novel regulatory sequence in the upstream region of the bovine TH gene promoter formed by a dyad symmetry element (DSE1;-352/-307 bp). DSE1 supports TH promoter activity in TH-expressing bovine adrenal medulla chromaffin (BAMC) cells and inhibits promoter activity in non-expressing TE671 cells. DNase I footprinting of relaxed TH promoter DNA showed weak binding of nuclear BAMC cell proteins to a short sequence in the right DSE1 arm. In BAMC cells, deletion of the right arm markedly reduced the expression of luciferase from the TH promoter. However, deletion of the left DSE1 arm or its reversed orientation (RevL) also inactivated the TH promoter. In supercoiled TH promoter, DSE1 assumes a cruciform-like conformation i.e., it binds cruciform-specific 2D3 antibody, and S1 nuclease-cleavage and OsO4-modification assays have identified an imperfect cruciform extruded by the DSE1. DNase I footprinting of supercoiled plasmid showed that cruciformed DSE1 is targeted by nuclear proteins more efficiently than the linear duplex isomer and that the protected site encompasses the left arm and center of DSE1. Our results suggest that the disruption of intrastrand base-pairing preventing cruciform formation and protein binding to DSE1 is responsible for its inactivation in DSE1 mutants. DSE1 cruciform may act as a target site for activator (BAMC cells) and repressor (TE671) proteins. Its extrusion emerges as a novel mechanism that controls cell-specific promoter activity.

GAA instability in Friedreich's Ataxia shares a common, DNA-directed and intraallelic mechanism with other trinucleotide diseases

We show that GAA instability in Friedreich's Ataxia is a DNA-directed mutation caused by improper DNA structure at the repeat region. Unlike CAG or CGG repeats, which form hairpins, GAA repeats form a YRY triple helix containing non-Watson-Crick pairs. As with hairpins, triplex mediates intergenerational instability in 96% of transmissions. In families with Friedreich's Ataxia, the only recessive trinucleotide disease, GAA instability is not a function of the number of long alleles, ruling out homologous recombination or gene conversion as a major mechanism. The similarity of mutation pattern among triple repeat-related diseases indicates that all trinucleotide instability occurs by a common, intraallelic mechanism that depends on DNA structure. Secondary structure mediates instability by creating strong polymerase pause sites at or within the repeats, facilitating slippage or sister chromatid exchange.

CTG repeats associated with human genetic disease are inherently flexible

The lengthening of tracts of CTG, CGG and GAA triplet repeats during progression of a pedigree has been associated with more than 12 human genetic diseases, including fragile X syndrome, myotonic dystrophy and Friedreich's ataxia. These repetitive sequence elements have the potential to form alternative DNA secondary structures that may contribute to their instability. The alternative DNA secondary structures may mediate errors during DNA replication, repair or recombination of the triplet repeat, leading to expansion. Here we show that DNA composed of pure CTG or CGG repeats exhibits anomalously fast mobility on polyacrylamide gels, confirming a previous observation for DNA containing CTG and CGG triplet repeats flanked by mixed sequence DNA. Moreover, we show that even short tracts of duplex CTG repeats have an unusual helix structure. CTG repeats reduce overall curvature associated with phased A-tract or GGCC curves, but alone they do not introduce curvature into DNA. The reduction in curvature of phased A-tracts by CTG repeats is similar to that afforded by an interspersed flexible region associated with a (TT).(TT) mispair. CTG-containing DNAs exhibit a rapid rate of cyclization, consistent with a flexible helix. These results suggest that tracts of (CTG).(CAG) repeats are inherently flexible. In addition, our results suggest that the unusual rapid electrophoretic mobility of CTG or CGG-containing DNA may be a consequence of an extended flexible DNA chain.

A 15-base acridine-conjugated oligodeoxynucleotide forms triplex DNA with its IL-2R alpha promoter target with greatly improved avidity

Attachment of 6,9-diamino-2-methoxyacridine to the 5' end of a purine-rich oligodeoxynucleotide targeting a 15 bp oligopurine oligopyrimidine stretch in the promoter region of the interleukin-2 receptor alpha chain (IL-2R alpha) gene results in an approximately 500-fold increase in its triplex forming avidity as determined by both band shift assay and DMS footprinting (Kd lowered from 2.5 microM to 5 nM). This oligonucleotide participates in Mg(2+)-dependent three-stranded DNA formation in which it is oriented antiparallel relative to the purine strand of the target duplex as determined by acridine moiety sensitized photoreactivity with the target duplex DNA. The oligonucleotides used in these studies were synthesized with a 3-amino-2-hydroxypropyl group at the 3' end to protect against exonucleolytic degradation for future in vivo applications. The 3'-amino group underwent partial removal, probably during the NaOH deprotection step. Both the 3'-amino and the 3'-free forms of the oligo have the same binding avidity and specificity. The interaction of the third strand with its target is sequence specific and can be essentially abolished by a point G-->T transversion 4 bases away from the 3' end of the target oligopurine block or severely reduced by other mutations within the target duplex. Thus, the attachment of the acridine moiety to the 5' end of the oligonucleotide does not seem to substantially compromise the sequence specificity of binding. Additionally, the oligonucleotide composed of G and A nucleotides was found to be superior to the oligonucleotide containing G and T residues since the difference in avidity of binding to the same target site was 17-fold.

Potential for H-DNA in the human MUC1 mucin gene promoter

Similar imperfect purine/pyrimidine mirror repeat (PMR) elements have previously been identified upstream of the human MUC1 mucin and CFTR genes. These elements confer S1 nuclease sensitivity on isolated plasmid DNA at low pH. We now present a detailed characterization of the non-B DNA structure responsible for S1 nuclease sensitivity upstream of the MUC1 gene. A approximately 90-base pair (bp) DNA fragment containing a 32-bp PMR element termed M-PMR3 was subcloned into a recombinant vector. This fragment conferred S1 nuclease sensitivity on the resulting supercoiled plasmid. High resolution mapping of sites reactive to S1 and P1 nucleases demonstrates that cleavage occurs within the M-PMR3 element. High resolution mapping with chemical agents selective for non-B DNA provides evidence that M-PMR3 adopts an H-DNA structure (intramolecular triple helix) in the less common H-y5 isomer at low pH. This result is observed in the presence or absence of Mg2+. Mutation of the native M-PMR3 element to create perfect homopurine/homopyrimidine mirror symmetry alters the preferred folding to the more common H-y3 triplex DNA isomer. These results demonstrate that imperfections in mirror symmetry can alter the relative stabilities of different H-DNA isomers.

TTA.TAA triplet repeats in plasmids form a non-H bonded structure

CTG.CAG, CGG.CCG, and AAG.CTT triplet repeats proximal to or in disease genes expand by a non-Mendelian genetic process to cause several human hereditary syndromes. As part of our physical, biological, and genetic studies on the 10 possible triplet repeats, we discovered that the TTA.TAA repeat, isolated from the upstream region of the variant surface glycoprotein gene of Trypanosoma brucei, shows a propensity to adopt a non-H bonded structure under appropriate conditions. The other nine triplet repeat sequences do not exhibit this property. (TTA.TAA)n, where n = 90, 60, 30, and 18, cloned into pUC19 was studied by chemical and enzymatic probes as well as two-dimensional gel electrophoretic analyses under a variety of conditions. The helix opening was observed for all four inserts in supercoiled plasmids as a function of temperature, pH, metal ions, and buffer conditions using OsO4, diethyl pyrocarbonate, and chloroacetaldehyde probes. This unusual property of the TTA.TAA repeat suggests that it plays a different role from the other nine triplet repeats in gene expression.

Cloning, characterization, and properties of seven triplet repeat DNA sequences

Several neuromuscular and neurodegenerative diseases are caused by genetically unstable triplet repeat sequences (CTG.CAG, CGG.CCG, or AAG.CTT) in or near the responsible genes. We implemented novel cloning strategies with chemically synthesized oligonucleotides to clone seven of the triplet repeat sequences (GTA.TAC, GAT.ATC, GTT.AAC, CAC.GTG, AGG.CCT, TCG.CGA, and AAG.CTT), and the adjoining paper (Ohshima, K., Kang, S., Larson, J. E., and Wells, R. D.(1996) J. Biol. Chem. 271, 16784-16791) describes studies on TTA.TAA. This approach in conjunction with in vivo expansion studies in Escherichia coli enabled the preparation of at least 81 plasmids containing the repeat sequences with lengths of approximately 16 up to 158 triplets in both orientations with varying extents of polymorphisms. The inserts were characterized by DNA sequencing as well as DNA polymerase pausings, two-dimensional agarose gel electrophoresis, and chemical probe analyses to evaluate the capacity to adopt negative supercoil induced non-B DNA conformations. AAG.CTT and AGG.CCT form intramolecular triplexes, and the other five repeat sequences do not form any previously characterized non-B structures. However, long tracts of TCG.CGA showed strong inhibition of DNA synthesis at specific loci in the repeats as seen in the cases of CTG.CAG and CGG.CCG (Kang, S., Ohshima, K., Shimizu, M., Amirhaeri, S., and Wells, R. D.(1995) J. Biol. Chem. 270, 27014-27021). This work along with other studies (Wells, R. D.(1996) J. Biol. Chem. 271, 2875-2878) on CTG.CAG, CGG.CCG, and TTA.TAA makes available long inserts of all 10 triplet repeat sequences for a variety of physical, molecular biological, genetic, and medical investigations. A model to explain the reduction in mRNA abundance in Friedreich's ataxia based on intermolecular triplex formation is proposed.

Size and genomic location of the pMGA multigene family of Mycoplasma gallisepticum

The pMGA multigene family encodes variant copies of the cell surface haemagglutinin of Mycoplasma gallisepticum. Quantitative Southern blotting, using an oligonucleotide probe complementary to a region conserved in the leader sequence of all known pMGA genes, was used to estimate the number of members of the family in the genome of seven strains of M. gallisepticum. The number of copies estimated to be present in the genome varied from 32 in strain F to 70 in strain R, indicating that the pMGA gene family may be second in size only to the tRNA family among prokaryotes. If all members of the pMGA family are of similar length to those which have been characterized, a minimum of 79 kb (7.7%) of the genome of strain S6, 82 kb (8.2%) of PG31 and 168 kb (16%) of the genome of strain R is dedicated to encoding variants of the same haemagglutinin. The GAA repeat motif identified in the intergenic region between all characterized pMGA genes appeared to be a feature common to most, if not all, pMGA genes, and furthermore probably exclusive to them. The genomic locations of members of the pMGA family were determined by PFGE and Southern blot hybridization of M. gallisepticum strain S6. The hybridizing regions were localized to four separate regions on the chromosome. The pMGA genes are likely to be predominantly arranged as tandem repeats within these regions, similar to the restricted regions for which the genomic sequence has been determined.

Both an altered DNA structure and cellular proteins are involved in protecting a triplex forming an oligopurine-rich sequence from Dam methylation in E. coli

When the 4-bp Dam recognition sequence was placed between two d(GA)7 tracts, it became severely undermethylated in JM101 Escherichia coli cells compared to other Dam sequences in the same plasmid DNA. This site specific undermethylation was also detected on supercoiled molecules in vitro. Mutational analysis indicated that undermethylation is related to the capacity of the oligopurine tract to adopt the H-DNA conformation. In addition, chemical probing of the cells was consistent with a cellular protein bound to the DNA. Therefore it is likely that the combination of altered DNA conformation and a cellular protein leads to Dam-site protection. We also found that the site-specific undermethylation is detectable in certain E. coli strains only.

A triplex DNA structure of the polypyrimidine: polypurine stretch in the 5' flanking region of the sea urchin arylsulfatase gene

Previously we reported that a long (522 bp) polypyrimidine: polypurine stretch in the 5' flanking region of the arylsulfatase gene of the sea urchin, Hemicentrotus pulcherrimus, took an unusual, perhaps triplex, DNA structure, when subjected to an acidic pH (pH 5) (Yamamoto et al., 1994). In the present study we have isolated a polypyrimidine: polypurine containing fragment from the arylsulfatase gene and surveyed the sensitivities of the polypyrimidine: polypurine stretch to base modification by diethylpyrocarbonate and osmium tetroxide under various levels of negative supercoiling. Based on the sensitivity of highly negatively supercoiled DNA to these base-modifying reagents, we conclude that, when highly negatively supercoiled, the polypyrimidine: polypurine stretch can take a triplex DNA structure even at a neutral pH and under physiological ionic strength in the presence of Mg2+.

Pausing of DNA synthesis in vitro at specific loci in CTG and CGG triplet repeats from human hereditary disease genes

Several human hereditary neuromuscular disease genes are associated with the expansion of CTG or CGG triplet repeats. The DNA syntheses of CTG triplets ranging from 17 to 180 and CGG repeats from 9 to 160 repeats in length were studied in vitro. Primer extensions using the Klenow fragment of DNA polymerase I, the modified T7 DNA polymerase (Sequenase), or the human DNA polymerase beta paused strongly at specific loci in the CTG repeats. The pausings were abolished by heating at 70 degrees C. As the length of the triplet repeats in duplex DNA, but not in single-stranded DNA, was increased, the magnitude of pausing increased. The location of the pause sites was determined by the distance between the site of primer hybridization and the beginning of the triplet repeats. CGG triplet repeats also showed similar, but not identical, patterns of pausings. These results indicate that appropriate lengths of the triplets adopt a non-B conformation(s) that blocks DNA polymerase progression; the resultant idling polymerase may catalyze slippages to give expanded sequences and hence provide the molecular basis for this non-Mendelian genetic process. These mechanisms, if present in human cells, may be related to the etiology of certain neuromuscular diseases such as myotonic dystrophy and Fragile X syndrome.

Intramolecular TAT triplex in (dA)58.(dT)58. influence of ions

Supercoil-stabilized intramolecular triplexes have been described under various conditions in different polypurine.polypyrimidine sequences such as (dG)n.(dC)n and mixed sequences including d(GA)n.d(CT)n while information about the triplexes in (dA)n.(dT)n is scarce. Using osmium tetroxide complexes and diethyl pyrocarbonate as structural probes, we show a pyrimidine.purine.pyrimidine (TAT) triplex in (dA)58.(dT)58 sequence in a supercoiled plasmid pE19. Strong modification of approximately six central thymines and approximately six T's at the 3'-end of the (dT)58 stretch as well as the DEPC modification of the 5'-half of the (dA)58 strand suggested the prevalence of the H-y3 triplex conformer. At native superhelix density, optimum conditions for the triplex formation were close to 1 mM MgCl2, pH 8.5. At room temperature and MgCl2 concentrations below 0.5 and above 5 mM, almost no triplex was formed. It is suggested that the absence of the triplex at higher MgCl2 concentrations is due to the stabilization of the duplex by Mg2+ ions which prevents the duplex opening necessary for the triplex formation. At higher temperatures, favorable for duplex opening (e.g. 55 degrees C), the TAT triplex is formed even in the presence of 10 mM MgCl2. Among Ca2+, Sr2+, Ba2+, Cd2+, Zn2+ and Ni2+, only Ca2+ and Sr2+ yielded a modification pattern similar to that obtained with Mg2+; the modification pattern produced in the presence of Sr2+ was, however, much less intense. In the presence of 1 mM MgCl2, a decrease in pH from 8.5 to 7.7 resulted in a strong decrease of the triplex content. At highly negative superhelix density, the conditions for triplex formation were less stringent, and the triplex was observed even in the absence of MgCl2.

A long purine-pyrimidine homopolymer acts as a transcriptional diode

Polypurine-polypyrimidine (R.Y) sequences have the unusual ability to form DNA triple helices. Such tracts are overrepresented upstream of eukaryotic genes, although a function there has not been clear. We report that transcription in vitro into one such upstream R.Y tract in the direction that makes a predominantly purine RNA is effectively blocked by formation of an intramolecular triple helix. The triplex is triggered by transcription and stabilized by the binding of nascent purine RNA to the template. Transcription in the opposite direction is not restricted. Polypurine-polypyrimidine DNA may provide a dynamic and selective block to transcription without the aid of accessory proteins.

Enzymatic and chemical probing of an S1 nuclease-sensitive site upstream from the human CFTR gene

Similar purine/pyrimidine mirror repeat (PMR) DNA sequences have been identified in the 5'-flanking regions of the human cystic fibrosis transmembrane conductance regulator (hCFTR) and mucin (hMUC1) genes, and supercoiled (but not linearized) plasmids containing these promoter regions were previously shown to be sensitive to digestion by S1 nuclease. The PMR element derived from the hCFTR promoter region is now sub-cloned and characterized at nucleotide resolution with respect to its reactivity toward nucleases S1 and P1, and toward the chemical probes dimethyl sulfate, chloroacetaldehyde, diethylpyrocarbonate and osmium tetroxide. These probes confirm the presence, at pH 4.5 (but not at pH 7.1), of a non-B-DNA structure. This non-B-DNA structure is distinct from H-DNA, because enzymatic and chemical probing detect single-stranded character in the absence of a stable intramolecular triple helix or extruded purine strand.

Complexes between osmium tetraoxide bispyridine and DNA: a molecular mechanics study

This study analyzes changes in conformation of five double-stranded DNA fragments related to binding of the single-strand selective probe osmium tetraoxide bispyridine (Os, py) to a thymine. Molecular mechanics was used to investigate four B-DNA and one A-DNA fragments including two structures containing a G.T mispair. The reactivity of a particular thymine was estimated by the difference in energies between interactions in a refined DNA fragment and the corresponding interactions in the transformed fragment with Os, py. Both calculations with and without counterions were performed and the results were in qualitative agreement with experiments. The energetically relaxed fragments with Os, py showed relatively minor global structural changes in comparison to the relaxed fragments without Os, py probe. The computed structures of fragments with Watson-Crick pairing that enable binding of Os, py had similar structural characteristics to geometries found in X-ray studies of single-base mismatches. The possible role of ions in binding Os, py to mispairs is also discussed.

Functional characterization of the rat GAP-43 promoter

GAP-43 is a highly conserved neuronal protein whose expression is spatially and temporally regulated. Because this regulation may occur, at least in part, at the level of transcription, we have begun to characterize the regions upstream of the GAP-43 transcription unit which direct its neuronal-specific expression. Functional analyses of GAP-43 promoter-reporter constructs have been performed in stably transfected cell lines, including PC12, C6 and RAT2. These data indicate that as little as 600 bp of GAP-43 5'-flanking DNA sequence directs the expression in a neuronal-specific manner. A shorter construct containing 230 bp of 5'-flanking DNA sequence defines a GAP-43 minimal promoter that is active in both neuronal and glial but not in non-neural cell lines. An upstream region, previously shown by other investigators to have promoter activity, was able to stimulate transcription when linked to the downstream minimal promoter. However, this upstream region was by itself unable to direct transcription of the reporting gene. In addition, we have demonstrated that two polypurine tracts within the 5'-flanking DNA sequence of the GAP-43 gene adopt a non-duplex configuration in plasmids, and, when studied in the context of chromosomal integration, these regions have a stimulatory effect on transcription.

The loop sequence plays crucial roles for isomerization of intramolecular DNA triplexes in supercoiled plasmids

The effect of base composition in the central region of polypurine.polypyrimidine (Pur.Pyr) tracts on the formation of intramolecular DNA triplexes in plasmids was examined using chemical probes (diethyl pyrocarbonate and OsO4), and two-dimensional (2-D) agarose gel electrophoresis. Two isomers exist for an intramolecular triplex: one with the 3'-half of the Pyr strand as the third strand (H-y3) and the other with the 5'-half of the Pyr strand as the third strand (H-y5). It was shown that the content and position of G + C residues in the triplex loop region (the center of Pur.Pyr tracts) are primary determinants for the isomerization between the H-y3 and H-y5 triplexes. Divalent metal ions such as Mg2+ and negative supercoiling also modulate the isomerization: the H-y5 conformation is stabilized by the divalent metal ions and/or under relatively lower negative supercoiling. 2-D gel analyses revealed that two isomers, H-y3 and H-y5, are topologically non-equivalent: the H-y3 formation relaxes one more supercoil turn than H-y5. As the G + C content in the center of Pur.Pyr tracts increases, the triplex requires more supercoil energy for formation. Therefore, the base-pair opening in the center of Pur.Pyr tracts is the initial and critical step in the pathway for the formation of triplex as well as the isomerization. The role of the triplex loop sequence is explained by a model in which the nucleation process of H-y3 formation requires a wide range of base-pair opening compared to that of H-y5: such unwinding would not be favored for the central region of the duplex with high G + C content and so it would be in the presence of Mg2+, and thereby the H-y5 formation is promoted.

Studies of DNA dumbbells. V. A DNA triplex formed between a 28 base-pair DNA dumbbell substrate and a 16 base linear single strand

CD spectra and melting curves were collected for a 28 base-pair DNA fragment in the form of a DNA dumbbell (linked on both ends by T4 single-strand loops) and the same DNA sequence in the linear form (without end loops). The central 16 base pairs (bp) of the 28-bp duplex region is the poly(pu) sequence: 5'-AGGAAGGAGGAAAGAG-3'. Mixtures of the dumbbell and linear DNAs with the 16-base single-strand sequence 5'-TCCTTCCTCCTTTCTC-3' were also prepared and studied. At 22 degrees C, CD measurements of the mixtures in 950 mM NaCl, 10 mM sodium acetate, 1 mM EDTA, pH 5.5, at a duplex concentration of 1.8 microM, provided evidence for triplex formation. Spectroscopic features of the triplexes formed with either a dumbbell or linear substrate were quite similar. Melting curves of the duplex molecules alone and in mixtures with the third strand were collected as a function of duplex concentration from 0.16 to 2.15 microM. Melting curves of the dumbbell alone and mixtures with the third strand were entirely independent of DNA concentration. In contrast, melting curves of the linear duplex alone or mixed with the third strand were concentration dependent. At identical duplex concentrations, the dumbbell alone melts approximately 20 degrees C higher than the linear duplex. The curve of the linear duplex displayed a significant pretransition probably due to end fraying. On melting curves of mixtures of the dumbbell or linear duplex with the third strand, a low temperature transition with much lower relative hyperchromicity change (approximately 5%) was observed. This transition was attributed to the melting of a new molecular species, e.g., the triplex formed between the duplex and single-strand DNA molecules. In the case of the dumbbell/single-strand mixture, these melting transitions of the triplex and the dumbbell were entirely resolvable. In contrast, the melting transitions of the linear duplex and the triplex overlapped, thereby preventing their clear distinction. To analyze the data, a three-state equilibrium model is presented. The analysis utilizes differences in relative absorbance vs temperature curves of dumbbells (or linear molecules) alone and in mixtures with the third strand.(ABSTRACT TRUNCATED AT 400 WORDS)