A long polypyrimidine/polypurine tract induces an altered DNA conformation on the 3'' coding region of the adjacent myosin heavy chain gene.

A long (147 base pairs), natural A.T rich polypyrimidine/polypurine tract has been found 55 base pairs downstream of a chicken embryonic myosin heavy chain (MHC) gene. Analysis at the nucleotide level of nicks induced by S1 and Neurospora crassa nucleases indicate that this long interrupted polypyrimidine/polypurine tract exists in an alternate DNA structure in vitro at pH 4.5 and pH 7.5 in both supercoiled and linear plasmid DNA. The polypyrimidine/polypurine tract induces this alternate structure upon at least 200 base pairs of its 5' flanking DNA, and thus extends into the 3' coding and non-coding regions of the neighboring MHC gene. The different nicking patterns induced by the nucleases S1 and N. crassa on each strand of this alternate structure suggests that the polypyrimidine/polypurine tract may form heteronomous DNA. When this long polypyrimidine/polypurine tract is present in a supercoiled plasmid at low pH, a new and as yet undefined S1 hypersensitive DNA alteration was detected near the center of this tract.     

The characterization of a mutant affecting DNA metabolism in the development of D. melanogaster

Using a "single-fly" nucleic acid hybridization method, we have surveyed a collection of D. melanogaster strains in search of variants which affect DNA complementary to the polypyrimidine sequence corresponding to one strand of the 1.705 satellite. Hybridization of labelled polypyrimidine probe to polypurine sequence in nucleic acid extracts of single flies, followed by thermal chromatography over hydroxyapatite led to the identification of one variant. The strain Cy/M(2)S2(10) produced excess hybrid, much of which had low thermal stability. A developmental analysis of the low-melt hybrid phenotype showed that certain tissues, in particular the ovaries, were affected. In addition to the biochemical phenotype, the break down of nurse cell nuclei in Cy/M(2)S2(10) ovaries during oocyte maturation was abnormal. A genetic analysis demonstrated that both the biochemical and cytological phenotypes were the consequences of a single recessive mutation in the DNase-1 gene on chromosome III. Studies with purified DNA demonstrated that the low-melt hybrid phenotype resulted from the accumulation of low molecular weight DNA complementary to the polypyrimidine probe.     

Evolution of Polypyrimidines in Drosophila

We surveyed 101 different Drosophila species for the presence of a particular highly repetitive DNA sequence containing long tracts of polypyrimidine/polypurine DNA, first found in D. melanogaster. Out of 55 tested species in the melanogaster group, only the sibling species D. simulans and D. mauritiana, as well as one distant relative in the ananassae subgroup, D. varians, contained the same sequence. All four of these species have long pyrimidine tracts as shown by acid hydrolysis of labelled DNA. All four species have the same sequence, bu the amount of this polypyrimidine/polypurine DNA varies greatly. Four other species in the hydei subgroup were found to contain a polypyrimidine/polpurine sequence, with an oligonucleotide composition different from that of D. melanogaster. This polypyrimidine DNA varies from as much as 10% of the total DNA in D. nigrohydei, to as little as 0.4% in D. neohydei. The long pyrimidine tracts in the hydei subgroup are often more than a thousand nucleotides in length, representing exceedingly homogeneous repetitious sequences.--These results show a rapid but discontinuous pattern of evolution for polypyrimidine/polypurine DNA . These sequences are not species specific, yet closely related species have greatly different amounts of polypyrimidines. Drastic changes occur in the amounts of these satellite type DNA sequences, as if the sequence had no continuous selective advantage in evolution. The implications of these results with regard to the general function and evolution of satellite DNA are discussed.     

Nucleic acid hybridization of highly repeated DNA in extracts of single Drosophila.

We have developed and characterized a method for the rapid detection and quantitation of specific DNAs in partially purified extracts of single Drosophila. While the method should be applicable to a number of repetitious DNA sequences, we have used the polypyrimidine DNA sequences (TCTCT)n to develop this technique. Using hydroxyapatite chromatography, we were able to measure the amount of nucleic acid hybrid formed and to obtain a thermal elution profile of the hybrid formed in extracts of single flies. Under a variety of conditions, purified DNA and DNA in partially purified extracts gave essentially identical results. The procedure can be used to detect the presence of rare sequences, or to measure the relative abundance of a prevalent DNA species. 40 different wild type strains of Drosophila melanogaster were examined using this technique and all contain similar amounts of the same polypyrimidine/polypurine sequence. From a small scale screening of different laboratory stocks of D. melanogaster, a variant was found which formed more DNA-DNA hybrid with labelled polypyrimidine tracts than did wild type. The additional hybrid was distinguished by a lower thermal stability than the hybrid formed in wild type.     

Loop organization of eukaryotic chromosomes and triple-stranded DNA structures

To study possible involvement of polypurine and polypyrimidine DNA tracts capable of forming triple-stranded structures (the H-form of DNA) in compaction of eukaryotic chromosomes, an in silico search for complementary polypurine and polypyrimidine sequences was carried out within 12 eukaryotic genes. It was shown that, in chromosomal gene loci, 10–11 bp polypurine and polypyrimidine tracts potentially capable of interacting with each other with the formation of triplex structures (“structuring” regions) are located in predominantly in introns and gene-flanking regions. In vivo, such DNA-DNA interactions can result in the chromosomal gene domain folding into several small loops. The character of the DNA triplex-mediated compaction of chromosomal gene loci may be related to gene functioning. A similar analysis of long (LINE) and short (SINE) interspersed repeat sequences, as well as of satellite DNA, showed essential resemblance between the compaction mechanisms of coding and noncoding chromosome regions.     

DNA structural transitions within the PKD1 gene.

Autosomal dominant polycystic kidney disease (ADPKD) affects over 500 000 Americans. Eighty-five percent of these patients have mutations in the PKD1 gene. The focal nature of cyst formation has recently been attributed to innate instability in the PKD1 gene. Intron 21 of this gene contains the largest polypurine. polypyrimidine tract (2.5 kb) identified to date in the human genome. Polypurine.polypyrimidine mirror repeats form intramolecular triplexes, which may predispose the gene to mutagenesis. A recombinant plasmid containing the entire PKD1 intron 21 was analyzed by two-dimensional gel electrophoresis and it exhibited sharp structural transitions under conditions of negative supercoiling and acidic pH. The superhelical density at which the transition occurred was linearly related to pH, consistent with formation of protonated DNA structures. P1 nuclease mapping studies of a plasmid containing the entire intron 21 identified four single-stranded regions where structural transitions occurred at low superhelical densities. Two-dimensional gel electrophoresis and chemical modification studies of the plasmid containing a 46 bp mirror repeat from one of the four regions demonstrated the formation of an H-y3 triplex structure. In summary, these experiments demonstrate that a 2500 bp polypurine.polypyrimidine tract within the PKD1 gene is capable of forming multiple non-B-DNA structures.     

Positive correlation between DNA polymerase alpha-primase pausing and mutagenesis within polypyrimidine/polypurine microsatellite sequences

Microsatellite DNA sequences are ubiquitous in the human genome, and mutation rates of these repetitive sequences vary with respect to DNA sequence as well as length. We have analyzed polymerase-DNA interactions as a function of microsatellite sequence, using polypyrimidine/polypurine di- and tetranucleotide alleles representative of those found in the human genome. Using an in vitro primer extension assay and the mammalian DNA polymerase alpha-primase complex, we have observed a polymerase termination profile for each microsatellite that is unique to that allele. Interestingly, a periodic termination profile with an interval size (9-11 nucleotides) unrelated to microsatellite unit length was observed for the [TC](20) and [TTCC](9) templates. In contrast, a unit-punctuated polymerase termination profile was found for the longer polypurine templates. We detected strong polymerase pauses within the [TC](20) allele at low reaction pH which were eliminated by the addition of deaza-dGTP, consistent with these specific pauses being a consequence of triplex DNA formation during DNA synthesis. Quantitatively, a strand bias was observed in the primer extension assay, in that polymerase synthesis termination is more intense when the polypurine sequence serves as the template, relative to its complementary polypyrimidine sequence. The HSV-tk forward mutation assay was utilized to determine the corresponding polymerase alpha-primase error frequencies and specificities at the microsatellite alleles. A higher microsatellite polymerase error frequency (50x10(-4) to 60x10(-4)) was measured when polypurine sequences serve as templates for DNA synthesis, relative to the polypyrimidine template (18x10(-4)). Thus, a positive correlation exists between polymerase alpha-primase pausing and mutagenesis within microsatellite DNA alleles.     

Stability of triple helices containing RNA and DNA strands: experimental and molecular modeling studies.

UV-absorption spectrophotometry and molecular modeling have been used to study the influence of the chemical nature of sugars (ribose or deoxyribose) on triple helix stability. For the Pyrimidine.purine* Pyrimidine motif, all eight combinations were tested with each of the three strands composed of either DNA or RNA. The chemical nature of sugars has a dramatic influence on triple helix stability. For each double helix composition, a more stable triple helix was formed when the third strand was RNA rather than DNA. No stable triple helix was detected when the polypurine sequence was made of RNA with a third strand made of DNA. Energy minimization studies using the JUMNA program suggested that interactions between the 2'-hydroxyl group of the third strand and the phosphates of the polypurine strand play an important role in determining the relative stabilities of triple-helical structures in which the polypyrimidine third strand is oriented parallel to the polypurine sequence. These interactions are not allowed when the third strand adopts an antiparallel orientation with respect to the target polypurine sequence, as observed when the third strand contains G and A or G and T/U. We show by footprinting and gel retardation experiments that an oligoribonucleotide containing G and A or G and U fails to bind double helical DNA, while the corresponding DNA oligomers form stable triple-helical complexes.     

Triplex‐Stabilizing Properties of Parallel Clamps Carrying LNA Derivatives at the Hoogsteen Strand

DNA Parallel clamps with a polypurine strand linked to a polypyrimidine Hoogsteen strand containing locked nucleic acids bind their corresponding polypyrimidine targets with high affinity.     

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.     

Polypurine.polypyrimidine sequences in complete bacterial genomes: preference for polypurines in protein-coding regions

The genomes of Methanococcus jannaschii, Mycoplasma genitalium, Haemophilus influenzae, Archaeoglobus fulgidus, Helicobacter pylori, Treponema pallidum, Borrelia burgdorferri, Rickettsia prowazekeii, Mycobacterium tuberculosis, Methanobacterium thermoautotrophicum, Synechocystis sp. PCC6803, Bacillus subtilis, Chlamydia trachomatis, Pyrococcus horikoshii, Aquifex aeolicus, Mycoplasma pneumoniae and Escherichia coli have been analysed for the presence of polypurine.polypyrimidine tracts, in order to understand their distribution in these genomes. We observed a variation in abundance of such sequences in these bacteria, with the archaeal genomes forming a high-abundance group and the canonical eubacteria forming a low-abundance group. The genomes of M. tuberculosis and A. aeolicus are unique among the organisms analysed here in the abnormal underrepresentation and overrepresentation of polypurine.polypyrimidine, respectively. We also observe a strand bias, i.e., a preferential occurrence of polypurines in coding strands. It varies widely among the bacteria, from the very high bias in M. jannaschii to the slightly inverse bias in the parasitic genomes of T. pallidum and C. trachomatis. The extent of strand bias, however, cannot be explained on the basis of the GC-content of the genome, use of all-purine codons or an excess in the amino acids that are encoded by such codons. The probable causes and effects of this phenomenon are discussed.     

Strand displacement of double-stranded DNA by triplex-forming antiparallel purine-hairpins

We characterize the binding affinity and the thermodynamics of hybridization of triplex-forming antiparallel purine-hairpins composed of two antiparallel purine domains linked by a loop directed toward single-stranded and double-stranded DNA (ssDNA, dsDNA). Gel retardation assays and melting experiments reveal that a 13-mer purine-hairpin binds specifically and with a K ( d ) of 8 x 10(8) M to polypyrimidine ssDNA to form a triple helical structure. Remarkably, we show that purine-hairpins also bind polypurine/polypyrimidine stretches included in a dsDNA of several hundred bp in length. Binding of purine-hairpins to dsDNA occurs by triplex formation with the polypyrimidine strand, causing displacement of the polypurine strand. Because triplex formation is restricted to polypurine/polypyrimidine stretches of dsDNA, we studied the triplex formation between purine-hairpins and polypyrimidine targets containing purine interruptions. We found that an 11-mer purine-hairpin with an adenine opposite to a guanine interruption in the polypyrimidine track binds to ssDNA and dsDNA, allowing expansion of the possible target sites and increase in the length of purine-hairpins. Thus, when using a 20-mer purine-hairpin targeting an interruption-containing polypyrimidine target, the binding affinity is increased compared to its 13-mer antiparallel purine-hairpin counterpart. Surprisingly, this increase is much more pronounced than that observed for a tail-clamp purine-hairpin extended up to 20 nt in the Watson-Crick domain only. Thus, triplexforming antiparallel purine-hairpins can be a potentially useful strategy for both single-strand and double-strand nucleic acid recognition.     

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

A conformational distortion in the DNA duplex at the regulatory region of human papillomavirus type-11 next to an intermolecular triplex, formed with a synthetic oligonucleotide, was investigated with several chemical probes. The sequence targeted for triplex formation borders on the binding sites for the regulatory proteins encoded by the viral E2 open reading frame. Dimethyl sulfate, diethyl pyrocarbonate, and OsO4 all react to a greater extent with nucleotides in the duplex that are immediately adjacent to the triplex as compared to other bases throughout the duplex. This hypermodification was observed on both the polypurine and polypyrimidine strands of the duplex DNA. Similar hyperreactivity of bases flanking a triplex also was seen when the contiguous target polypurine tract was effectively extended by mutating interrupting pyrimidines in the human papillomavirus type-11 sequence to purines. We propose that this hyperreactivity is due to a structural distortion caused by the junction between the triplex and the duplex tracts.     

The promoter of the C1 inhibitor gene contains a polypurine.polypyrimidine segment that enhances transcriptional activity.

The C1 inhibitor (C1INH) promoter is unusual in two respects: 1) It contains no TATA sequence, but instead contains a TdT-like initiator element (Inr) at nucleotides -3 to +5; 2) it contains a polypurine.polypyrimidine tract between nucleotides -17 and -45. Disruption of the Inr by the introduction of point mutations reduced promoter activity by 40%. A TATA element inserted at nucleotide -30 in the wild-type promoter and in promoter constructs containing the mutated Inr led to a 2-fold increase in basal promoter activity. Previous studies suggested that the potential hinged DNA-forming polypurine.polypyrimidine tract might be important in the regulation of C1INH promoter activity. The present studies indicate that this region is capable of such intramolecular triple helix formation. Disruption of the polypurine.polypyrimidine sequence by substitution of 5 of the 23 cytosine residues with adenine prevented triple helix formation. Site-directed mutagenesis experiments demonstrate that the regulation of promoter activity is independent of hinged DNA-forming capacity but requires an intact AC box (ACCCTNNNNNACCCT) or the overlapping PuF binding site (GGGTGGG). The C1INH gene also contains a number of potential regulatory elements, including an Sp-1 and an hepatocyte nuclear factor-1 binding site and a CAAT box. The role of these elements in regulation of the C1INH promoter was examined. Elimination of the hepatocyte nuclear factor-1 site at nucleotides -94 to -81 by truncation reduced the activity of the promoter by approximately 50%. Similarly, site-directed mutations that disrupt this site reduce promoter activity by 70%.     

Multiple non-B-DNA conformations of polypurine.polypyrimidine sequences in plasmids

A polypurine.polypyrimidine (Pur.Pyr) sequence with a central interruption in a plasmid can adopt multiple non-B-DNA conformations depending on the conditions as revealed by specific chemical probes (OsO4, diethyl pyrocarbonate, and dimethyl sulfate) and two-dimensional electrophoresis. The relatively long mirror repeat Pur.Pyr sequences (GAA)9TTC(GAA)8 and (GGA)9TCC(GGA)8 form single canonical intramolecular triplexes at pH 7.0-6.0 in negatively supercoiled plasmids as isolated from Escherichia coli. With a lowering of the pH and/or an increase in the degree of negative supercoiling, these sequences undergo a novel conformational change as revealed by diethyl pyrocarbonate hypermodification of adenines in the middle of the polypurine strand and OsO4 reaction with thymines in the center and the quarter points of the polypyrimidine strand. To evaluate this structure, a family of related Pur.Pyr sequences were cloned and studied. The non mirror repeat sequence (GGA)9TCC(GAA)8 forms a non-B conformation only under acidic pH conditions, but the structural properties are different from those of the mirror repeat sequences. Furthermore, when the central interruptions of a mirror repeat sequence were increased from 3 to 9 bp, two canonical triplexes formed independently at pH 5.0 [at the (GAA)9 and (GAA)8 regions in the sequence (GAA)9TTAATTCGC(GAA)8]. Thus, if an interruption is sufficiently long, the two halves of the Pur.Pyr sequence do not interact with each other. Novel types of folded DNA geometries which explain these results are described.     

RecQ and RecG helicases have distinct roles in maintaining the stability of polypurine.polypyrimidine sequences

DNA triplex structures can block the replication fork and result in double-stranded DNA breaks (DSBs). RecQ and RecG helicases may be important for replication of such sequences as RecQ resolves synthetic triplex DNA structures and RecG mediates replication restart by fork regression. Primer extension on an 88bp triplex-forming polypurine.polypyrimidine (Pu.Py) tract from the PKD1 gene demonstrated that RecQ, but not RecG, facilitated primer extension by T7 DNA polymerase. A high-throughput, dual plasmid screening system using isogenic bacterial lines deficient in RecG, RecQ, or both, revealed that RecQ deficiency increased mutation to sequence flanking this 88bp tract by eight to ten-fold. Although RecG facilitated small deletions in an 88bp mirror repeat-containing sequence, it was absolutely required to maintain a 2.5kb Pu.Py tract containing multiple mirror repeats. These results support a two-tiered model where RecQ facilitates fork progression through triplex-forming tracts and, failing processivity, RecG is critical for replication fork restart.     

The structure of the guanine-rich polypurine:polypyrimidine sequence at the right end of the rat L1 (LINE) element

We report here that the 64-base pair (bp) guanine-rich polypurine:polypyrimidine tract derived from the right end of the rat long interspersed DNA element is reactive in a supercoil-dependent manner with a variety of chemical probes of non-B DNA structure. At pH 5.0 in the presence of Mg2+, part of the sequence (position 10-40) forms the following two types of triplexes: a G.G.C triplex, and an unusual C.G.C triplex. The latter structure is much more prevalent than the former and is unusual in that the resultant free purine strand forms a hairpin loop. In the absence of Mg2+ the G.G.C triplex disappears and the amount of C.G.C triplex is diminished, and at pH 7.5 in the presence or absence of Mg2+, little or no triplex is observed. Deletion of the 24-bp region just 3' of the triplex-forming region greatly reduces the amount of triplex formed. In this region, which includes an 18-bp polypurine:polypyrimidine sequence, both strands exhibit a moderate symmetric reactivity with the chemical probes tested, independent of pH and Mg2+. The implications of this structurally complex region for the properties of the rat L1 element are discussed.     

Nodule DNA in the (GA)37.(CT)37 insert in superhelical plasmids.

Di- or trivalent metal ions stabilize a supercoil-dependent transition in pGA37, which contains the (GA)37.(CT)37 insert, at neutral and basic pH. The structure formed is different from the well known protonated triplexes (H-DNA) adopted at low pH by polypurine.polypyrimidine (Pur.Pyr) inserts in plasmids. DNA samples must be preincubated in the presence of multivalent ions at 50 degrees C for the new transition to occur. At neutral pH in the presence of Co hexamine, both strands of the insert have modification maxima situated at one-third of the distance from both ends. We propose the formation of a new structure called nodule DNA which consists of both Pyr.Pur.Pyr and Pur.Pur.Pyr triplexes and does not contain continuous single-stranded regions. At basic pH (greater than 8.5) in the presence of magnesium ions, the modification pattern corresponds to Pur.Pur.Pyr triplex formation in the whole insert. At neutral pH in the presence of magnesium, both nodule DNA and the Pur.Pur.Pyr triplex can be formed in the insert. We also observed a magnesium-dependent transition at neutral pH in the other Pur.Pyr insert containing plasmids. These data demonstrate that Pur.Pyr sequences can adopt several non-B conformations at close to in vivo conditions.