Unusual DNA Conformation Research Articles

Two sequential cleavage reactions on cruciform DNA structures cause palindrome-mediated chromosomal translocations

Gross chromosomal rearrangements (GCRs), such as translocations, deletions or inversions, are often generated by illegitimate repair between two DNA breakages at regions with nucleotide sequences that might potentially adopt a non-B DNA conformation. We previously established a plasmid-based model system that recapitulates palindrome-mediated recurrent chromosomal translocations in humans, and demonstrated that cruciform DNA conformation is required for the translocation-like rearrangements. Here we show that two sequential reactions that cleave the cruciform structures give rise to the translocation: GEN1-mediated resolution that cleaves diagonally at the four-way junction of the cruciform and Artemis-mediated opening of the subsequently formed hairpin ends. Indeed, translocation products in human sperm reveal the remnants of this two-step mechanism. These two intrinsic pathways that normally fulfil vital functions independently, Holliday-junction resolution in homologous recombination and coding joint formation in rearrangement of antigen-receptor genes, act upon the unusual DNA conformation in concert and lead to a subset of recurrent GCRs in humans.

Expansion of microsatellites on evolutionary young Y chromosome.

Sex chromosomes are an ideal system to study processes connected with suppressed recombination. We found evidence of microsatellite expansion, on the relatively young Y chromosome of the dioecious plant sorrel (Rumex acetosa, XY1Y2 system), but no such expansion on the more ancient Y chromosomes of liverwort (Marchantia polymorpha) and human. The most expanding motifs were AC and AAC, which also showed periodicity of array length, indicating the importance of beginnings and ends of arrays. Our data indicate that abundance of microsatellites in genomes depends on the inherent expansion potential of specific motifs, which could be related to their stability and ability to adopt unusual DNA conformations. We also found that the abundance of microsatellites is higher in the neighborhood of transposable elements (TEs) suggesting that microsatellites are probably targets for TE insertions. This evidence suggests that microsatellite expansion is an early event shaping the Y chromosome where this process is not opposed by recombination, while accumulation of TEs and chromosome shrinkage predominate later.

Mid-Range Inhomogeneity of Eukaryotic Genomes

Multicellular eukaryotic genomes are replete with nonprotein coding sequences, both within genes (introns) and between them (intergenic regions). Excluding the well-recognized functional elements within these sequences (ncRNAs, transcription factor binding sites, intronic enhancers/silencers, etc.), the remaining portion is made up of so-called “dark” DNA, which still occupies the majority of the genome. This dark DNA has a profound nonrandomness in its sequence composition seen at different scales, from a few nucleotides to regions that span over hundreds of thousands of nucleotides. At the mid-range scale (from 30 up to 10,000 nt), this nonrandomness is manifested in base compositional extremes detected for each of four nucleotides (A, G, T, or C) or any of their combinations. Examples of such compositional nonrandomness are A-rich, purine-rich, or G+T-rich regions. Almost every combination of nucleotides has such enriched regions. We refer to these regions as being “inhomogeneous”. These regions are associated with unusual DNA conformations and/or particular DNA properties. In particular, mid-range inhomogeneous regions have complex arrangements relative to each other and to specific genomic sites, such as centromeres, telomeres, and promoters, pointing to their important role in genomic functioning and organization.

DNA models of trinucleotide frameshift deletions: the formation of loops and bulges at the primer–template junction

Although mechanisms of single-nucleotide residue deletion have been investigated, processes involved in the loss of longer nucleotide sequences during DNA replication are poorly understood. Previous reports have shown that in vitro replication of a 3′-TGC TGC template sequence can result in the deletion of one 3′-TGC. We have used low-energy circular dichroism (CD) and fluorescence spectroscopy to investigate the conformations and stabilities of DNA models of the replication intermediates that may be implicated in this frameshift. Pyrrolocytosine or 2-aminopurine residues, site-specifically substituted for cytosine or adenine in the vicinity of extruded base sequences, were used as spectroscopic probes to examine local DNA conformations. An equilibrium mixture of four hybridization conformations was observed when template bases looped-out as a bulge, i.e. a structure flanked on both sides by duplex DNA. In contrast, a single-loop structure with an unusual unstacked DNA conformation at its downstream edge was observed when the extruded bases were positioned at the primer–template junction, showing that misalignments can be modified by neighboring DNA secondary structure. These results must be taken into account in considering the genetic and biochemical mechanisms of frameshift mutagenesis in polymerase-driven DNA replication.

Chromosomal instability mediated by non-B DNA: Cruciform conformation and not DNA sequence is responsible for recurrent translocation in humans

Chromosomal aberrations have been thought to be random events. However, recent findings introduce a new paradigm in which certain DNA segments have the potential to adopt unusual conformations that lead to genomic instability and nonrandom chromosomal rearrangement. One of the best-studied examples is the palindromic AT-rich repeat (PATRR), which induces recurrent constitutional translocations in humans. Here, we established a plasmid-based model that promotes frequent intermolecular rearrangements between two PATRRs in HEK293 cells. In this model system, the proportion of PATRR plasmid that extrudes a cruciform structure correlates to the levels of rearrangement. Our data suggest that PATRR-mediated translocations are attributable to unusual DNA conformations that confer a common pathway for chromosomal rearrangements in humans.

Gene-based approaches toward Friedreich ataxia therapeutics.

Friedreich ataxia is an autosomal recessive trinucleotide-repeat disease caused by expanded GAA repeats in the first intron of the FRDA gene. These GAA repeats are suspected to form unusual non-B DNA conformations that decrease transcription and subsequently reduce levels of the encoded protein, frataxin. GAA repeats also induce heterochromatin formation and silencing of the frataxin gene locus. Frataxin plays a crucial role in iron metabolism and detoxification and interacts with electron transport chain proteins. There is no effective therapy for Friedreich ataxia, but antioxidant therapy has shown promise and is currently in clinical trials. In this review we focus on the mechanisms by which expanded GAA repeats reduce transcription and discuss how these findings have lead to gene-based approaches that may be effective in treating Friedreich ataxia.

Effect of DNA Supercoiling on the Geometry of Holliday Junctions

Unusual DNA conformations including cruciforms play an important role in gene regulation and various DNA transactions. Cruciforms are also the models for Holliday junctions, the transient DNA conformations critically involved in DNA homologous and site-specific recombination, repair, and replication. Although the conformations of immobile Holliday junctions in linear DNA molecules have been analyzed with the use of various techniques, the role of DNA supercoiling has not been studied systematically. We utilized atomic force microscopy (AFM) to visualize cruciform geometry in plasmid DNA with different superhelical densities at various ionic conditions. Both folded and unfolded conformations of the cruciform were identified, and the data showed that DNA supercoiling shifts the equilibrium between folded and unfolded conformations of the cruciform toward the folded one. In topoisomers with low superhelical density, the population of the folded conformation is 50-80%, depending upon the ionic strength of the buffer and a type of cation added, whereas in the sample with high superhelical density, this population is as high as 98-100%. The time-lapse studies in aqueous solutions allowed us to observe the conformational transition of the cruciform directly. The time-dependent dynamics of the cruciform correlates with the structural changes revealed by the ensemble-averaged analysis of dry samples. Altogether, the data obtained show directly that DNA supercoiling is the major factor determining the Holliday junction conformation.

Rational selection of small molecules that increase transcription through the GAA repeats found in Friedreich’s ataxia

Friedreich’s ataxia (FRDA) is an autosomal recessive trinucleotide repeat disease with no effective therapy. Expanded GAA repeats in the first intron of the FRDA gene are thought to form unusual non-B DNA conformations that decrease transcription and subsequently reduce levels of the encoded protein, frataxin. Frataxin plays a crucial role in iron metabolism and detoxification. To discover small molecules that increase transcription through the GAA repeat region in FRDA, we have made stable cell lines containing a portion of expanded intron 1 fused to a GFP reporter. Small molecules identified using the competition dialysis method were found to increase FRDA-intron 1-reporter gene expression. One of these compounds, pentamidine, increases frataxin levels in patient cells. Thus our approach can be used to detect small molecules of potential therapeutic value in FRDA.

Sticky DNA Formation in Vivo Alters the Plasmid Dimer/Monomer Ratio

Our discovery that plasmids containing the Friedreich's ataxia (FRDA) expanded GAA.TTC sequence, which forms sticky DNA, are prone to form dimers compared with monomers in vivo is the basis of an intracellular assay in Escherichia coli for this unusual DNA conformation. Sticky DNA is a single long GAA.GAA.TTC triplex formed in plasmids harboring a pair of long GAA.TTC repeat tracts in the direct repeat orientation. This requirement is fulfilled by either plasmid dimers of DNAs with a single trinucleotide repeat sequence tract or by monomeric DNAs containing a pair of direct repeat GAA.TTC sequences. DNAs harboring a single GAA.TTC repeat are unable to form this type of triplex conformation. An excellent correlation was observed between the ability of a plasmid to adopt the sticky triplex conformation as assayed in vitro and its propensity to form plasmid dimers relative to monomers in vivo. The variables measured that strongly influenced these measurements are as follows: length of the GAA.TTC insert; the extent of periodic interruptions within the repeat sequence; the orientation of the repeat inserts; and the in vivo negative supercoil density. Nitrogen mustard cross-linking studies on a family of GAA.TTC-containing plasmids showed the presence of sticky DNA in vivo and, thus, serves as an important bridge between the in vitro and in vivo determinations. Biochemical genetic studies on FRDA containing DNAs grown in recA or nucleotide excision repair or ruv-deficient cells showed that the in vivo properties of sticky DNA play an important role in the monomer-dimer-sticky DNA intracellular intercon-versions. Thus, the sticky DNA triplex exists and functions in living cells, strengthening the likelihood of its role in the etiology of FRDA.

Sticky DNA: Effect of the Polypurine·Polypyrimidine Sequence

The polypurine.polypyrimidine sequence requirements for the formation of sticky DNA were evaluated in Escherichia coli plasmid systems to determine the potential occurrence of this conformation throughout biological systems. A mirror repeat, dinucleotide tract of (GA.TC)(37), which is ubiquitous in eukaryotes, formed sticky DNA, but shorter sequences of 10 or 20 repeats were inert. (GGA.TCC)(n) inserts (where n = 126, 159, and 222 bp) also formed sticky DNA. As shown previously, the control sequence (GAA.TTC)(150) (450 bp) readily adopted the X-shaped sticky structure; however, this structure has never been found for the nonpathogenic (GAAGGA.TCCTTC)(65) of the same approximate length (390 bp). A sequence that is replete with polypurine.polypyrimidine tracts that can form triplexes and slipped structures but lacks long repeating motifs (the 2.5-kbp intron 21 sequence from the polycystic kidney disease gene 1) was also inert. Interestingly, tracts of (GAA.TTC)(n) (where n = 176 or 80) readily formed sticky DNA with (GAAGGA.TCCTTC)(65) cloned into the same plasmid when the pair of inserts was in the direct, but not in the indirect (inverted), orientation. The stabilities of the triple base (Watson-Crick and Hoogsteen) interactions in the DNA/DNA associated triplex region of the sticky conformations account for these observations. Our results have significant chemical and biological implications for the structure and function of this unusual DNA conformation in Friedreich's ataxia.

Unusual DNA Conformations: Implications for Telomeres

DNA is prone to structural polymorphism: its three-dimensional structure can differ markedly from the classical double helix. Nucleic acid structures composed of more than two strands have also been observed. The guanine-rich sequence of both the telomere and centromere can form a quadruplex based on G-quartets while the complementary cytosine-rich strand can fold into an intercalated tetramer called the i-motif. The G-quartet is a gold mine for structural biologists and the telomere has become a target for anti-cancer drug design since it was observed that deregulation of telomerase favors proliferation of certain tumors. Other DNA sequences may adopt unusual conformations. Polypurine-polypyrimidine sequences capable of forming a triple-stranded structure called H-DNA are found abundantly in the eukaryotic genome and may play a significant role in DNA metabolism, transcription and replication. Triplex-forming oligonucleotides are currently being developed as "anti-gene" agents. Unusual DNA structures may therefore be implicated in fundamental processes such as gene expression and represent unique targets for both structural-specific and sequence-specific agents. In this review, we present work characterizing some of these unusual conformations in terms of structure, stability and formation kinetics and discuss their biological implications.

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.

Destabilization of nucleosomes by an unusual DNA conformation adopted by poly(dA) small middle dotpoly(dT) tracts in vivo.

Poly(dA) small middle dotpoly(dT) tracts are common and often found upstream of genes in eukaryotes. It has been suggested that poly(dA) small middle dotpoly(dT) promotes transcription in vivo by affecting nucleosome formation. On the other hand, in vitro studies show that poly(dA) small middle dotpoly(dT) can be easily incorporated into nucleosomes. Therefore, the roles of these tracts in nucleosome organization in vivo remain to be established. We have developed an assay system that can evaluate nucleosome formation in yeast cells, and demonstrated that relatively longer tracts such as A(15)TATA(16) and A(34) disrupt an array of positioned nucleosomes, whereas a shorter A(5)TATA(4) tract is incorporated in positioned nucleosomes of yeast minichromosomes. Thus, nucleosomes are destabilized by poly(dA) small middle dotpoly(dT) in vivo in a length-dependent manner. Furthermore, in vivo UV footprinting revealed that the longer tracts adopt an unusual DNA structure in yeast cells that corresponds to the B' conformation described in vitro. Our results support a mechanism in which a unique poly(dA) small middle dot poly(dT) conformation presets chromatin structure to which transcription factors are accessible.

Three-Dimensional Model for Slipped Loop RNA

Earlier a three-dimensional model for a new unusual DNA conformation referred to as Slipped Loop Structure (SLS) has been suggested by us (1). The same type of folding could occur with RNA as well which means that one must use the A-form of the double helix rather than the B-one. The present paper discusses the creation of an all-atom stereochemically sound model for SLS-RNA. This calculated model, while possessing the same folding topology as the SLS-DNA, differs dramatically from the SLS-DNA by an overall folding geometry. It also differs radically from the RNA-pseudoknot and can thus be regarded as a new type of an RNA folding.

Hairpin formation during DNA synthesis primer realignment in vitro in triplet repeat sequences from human hereditary disease genes.

Genetic expansion of DNA triplet repeat sequences (TRS) found in neurogenetic disorders may be due to abnormal DNA replication. We have previously observed strong DNA synthesis pausings at specific loci within the long tracts (> approximately 70 repeats) of CTG.CAG and CGG.CCG as well as GTC.GAC by primer extensions in vitro using DNA polymerases (the Klenow fragment of Escherichia coli DNA polymerase I, the modified T7 DNA polymerase (Sequenase), and human DNA polymerase beta). Herein, we have isolated and analyzed the products of stalled synthesis found at approximately 30-40 triplets from the beginning of the TRS. DNA sequence analyses revealed that the stalled products contained short tracts of homogeneous TRS (6-12 repeats) in the middle of the sequence corresponding to the flanking region of the primer-template sequence. The sequence at the 3'-side terminated at the end of the primer, indicating that the primer molecule had served as a template. In addition, chemical probe and polyacrylamide gel electrophoretic analyses revealed that the stalled products existed in hairpin structures. We postulate that these products of the DNA polymerases are caused by the existence of an unusual DNA conformation(s) within the TRS, during the in vitro DNA synthesis, enhancing the DNA slippages and the hairpin formations in the TRS due to primer realignment. The consequence of these steps is DNA synthesis to the end of the primer and termination. Primer realignment including hairpin formation may play an important intermediate role in the replication of TRS in vivo to elicit genetic expansions.

Interstrand cross-linking by bizelesin produces a Watson-Crick to Hoogsteen base-pairing transition region in d(CGTAATTACG)2.

1H NMR analysis of the bizelesin adduct of d(CGTAATTACG)2 indicates that adenines six base pairs apart on opposite DNA strands are cross-linked, yielding two major adduct conformations differing in the central duplex region (5'AATT-3'): one (major product) contains an AT step wherein both adenines are syn-oriented and Hoogsteen base paired to thymines (5HG model); the other contains anti-oriented AT-step adenines that show no evidence of hydrogen bonding with pairing thymines (5OP model). The 5OP model consists of three conformers undergoing exchange and differing in the orientation of the AT-step thymines. Bizelesin's size, rigidity, and cross-linking properties restrict the DNA adduct's range of motion and freeze out DNA conformation(s) adopted during the cross-linking process. This most reactive DNA sequence, 5'-TAATTA-3', yields an adduct conformation (5HG) containing a stable region of Watson-Crick (WC) to Hoogsteen (HG) to Watson-Crick base-pairing transitions. While bizelesin exercises a selective effect on DNA conformation, it intrudes into regions of base stacking less than other Hoogsteen pairing-inducing drugs (e.g., echinomycin). Because of this capacity to induce stable Hoogsteen base pairing with only minimal distortion of base-base stacking, bizelesin affords an opportunity to explore this unusual DNA conformation.

Further characterization of an amsacrine-resistant line of HL-60 human leukemia cells and its topoisomerase II: Effects of ATP concentration, anion concentration, and the three-dimensional structure of the DNA target

The characterization of type II topoisomerases from amsacrine-sensitive (HL-60) and amsacrine-resistant (HL-60/AMSA) human leukemia cells was extended. The intercalator resistance and etoposide sensitivity of the HL-60/AMSA cells themselves were confirmed, and the stability of this pharmacologic phenotype over many hundreds of cell generations was demonstrated. Prolonging exposure of HL-60/AMSA cells to amsacrine did not alter their sensitivity relative to that of HL-60 cells. Improved methods of immunoblotting allowed clear demonstration that the topoisomerase II within these cells exhibited sensitivity and resistance characteristics that mirrored those of the cells and the isolated enzymes themselves. Additional biochemical characterization of the type II topoisomerases indicated that both enzymes relaxed supercoiled DNA in a distributive fashion and that the ATP concentrations at which optimal catalytic activity of the two enzymes was exhibited were identical. The enzymes differed, however, in their activity optima in buffers of various type and ionic strength. Furthermore, the inability of the HL-60/AMSA enzyme to exhibit enhanced DNA cleavage in the presence of amsacrine could be overcome if the DNA target molecule contained a bend cloned into its polylinker region. By contrast, a bend in a DNA plasmid containing no polylinker was resitant to amsacrine-enhanced cleavage in the presence of HL-60/AMSA topoisomerase II, as was a plasmid containing a polylinker with no bend. This suggests that an unusual DNA conformation (a bend) in a specific DNA context (a polylinker) may be favoured site for topoisomerase II action. It also suggests a mechanism by which the sites and extent of topoisomerase II activity can be controlled in cells.

Intramolecular DNA triplexes: unusual sequence requirements and influence on DNA polymerization.

Homopurine-homopyrimidine mirror repeats are known to form intramolecular DNA triplexes in vitro. By probing with chemical agents specific for unusual DNA conformations, we have now demonstrated the formation of intramolecular triplexes consisting of G.G.C and T.A.T base triplets by DNA sequences that are neither homopurine-homopyrimidine nor mirror repeats. This finding significantly enlarges the number of sequences that could form DNA triplexes. The observed triplexes are stable under the conditions that are optimal for DNA polymerases in vitro. We found that triplex formation causes specific termination of DNA polymerization in vitro. This effect is detected for different DNA polymerases and may have implications for the regulation of DNA replication in vivo.

Unusual DNA conformation at low pH revealed by NMR: parallel-stranded DNA duplex with homo base pairs.

We have investigated the conformational potentials of several DNA oligonucleotides containing sequences related to 5'-CGA in neutral pH and low pH (< 5.0) conditions. One-dimensional proton NMR spectra show that d(CGATCG), d(TCGATCGA), and d(CGATCGATCG) exhibit new sets of resonances at low pH (approximately 3.8-4.4), when compared to those from the neutral pH samples. The low pH form and the neutral pH form are in slow equilibrium. Analyses of the data suggest that these sequences under low pH conditions adopt structures distinct from B-DNA. Two-dimensional nuclear Overhauser effect spectroscopy (2D NOESY) data from the DNA hexamer d(CGATCG) of the neutral and low pH samples were used to analyze their respective structures in solution. An iterative NOE spectral-driven refinement procedure, SPEDREF [Robinson, H., & Wang, A. H.-J. (1992) Biochemistry 31, 3524-3533], was used to show that the neutral pH structure is close to canonical B-DNA. In contrast, analysis of the low pH form using the 2D NOESY data suggests that its structure is consistent with a right-handed parallel-stranded (PS) double helix with symmetrical non-Watson-Crick (C+:C, G:G, A:A, T:T) homo base pairs. Supporting evidence for the PS helix includes the asymmetric inversion-recovery relaxation times associated with the two ends of the helix. The structure is favored by the 5'-CGA sequence in which the cytosines provide the C+:C pairing for the nucleation step and the GpA step is significantly stabilized by the interstrand G-A stacking interactions.(ABSTRACT TRUNCATED AT 250 WORDS)

A neural-specific GAP-43 core promoter located between unusual DNA elements that interact to regulate its activity

In an effort to identify cis-acting elements that respond to signals controlling different stages of neural differentiation, we have analyzed the promoter and surrounding regulatory sequences of the rat GAP-43 gene. Expression of this gene is both neural specific and, within neurons, strongly modulated by signals related to axon integrity. Expression analysis in cell lines and primary rat cortical cultures demonstrates that neural-selective gene expression can be directed by a 386 base pair GAP-43 promoter fragment that contains canonical TATA and CCAAT box consensus sequences. A short region of homology with other neural-specific genes, identified upstream of the core promoter, is not essential for selective expression in neuronal cells. Within cortical cell cultures, expression is strongly modulated by two interacting elements on either side of the promoter, each of which contains a sequence with the potential to adopt an unusual DNA conformation. While each of these flanking elements reduces expression when added alone to the core promoter, each counteracts the negative influence of the other when both elements are present.