Separation of triplet repeat DNA by capillary electrophoresis and the conformational analysis by atomic force microscope.

We investigated the relationship between electrophoretic behaviors and higher order structures of triplet repeat DNA fragments by means of capillary electrophoresis and atomic force microscopy (AFM). It was suggested that the mobility difference between triplet repeat DNA and random sequence DNA should be correlated to differences in their dynamic conformation.     

Evolutionary origin of expandable G-C-rich triplet repeat DNA sequences

A model explaining properties exhibited by fragile-X DNA systems arises from observations that time-dependent base substitutions are expressed at G-C sites but not at A–T sites (Biochem. Genet.32:383, 1994). [CGG]_n sequences are classified as most sensitive to evolutionary base substitution processes involving time-dependent populating of G-C sites with enol-imine states having enhanced stability. Increased density of these states in oocyte DNA would introduce a ground-state collapse double-helix of reduced energy that would inhibit strand separation by the replicase. Evolutionarily altered G in CGG triplets allows CGG to be transcribed as CTG, an initiation codon. And this will cause reinitiation of DNA synthesis, thereby adding additional CGG units to the collapsed double helix. This situation would not occur in slower-evolving male haploid DNA that replicates frequently.     

Base stacking and even/odd behavior of hairpin loops in DNA triplet repeat slippage and expansion with DNA polymerase

Repetitions of CAG or CTG triplets in DNA can form intrastrand hairpin loops with combinations of normal and mismatched base pairs that easily rearrange. Such loops may promote primer-template slippage in DNA replication or repair to give triplet-repeat expansions like those associated with neurodegenerative diseases. Using self-priming sequences (e.g. (CAG)(16)(CTG)(4)), we resolve all hairpin loops formed and measure their slippage and expansion rates with DNA polymerase at 37 degrees C. Comparing CAG/CTG loop structures with GAC/GTC structures, having similar hydrogen bonding but different base stacking, we find that CAG, CTG, and GTC triplets predominantly form even-membered loops that slip in steps of two triplets, whereas GAC triplets favor odd-numbered loops. Slippage rates decline as hairpin stability increases, supporting the idea that slippage initiates more easily in less stable regions. Loop stabilities (in low salt) increase in the order GTC < CAG < GAC < CTG, while slippage rates decrease in the order GTC > CAG approximately GAC > CTG. Loops of GTC compared with CTG melt 9 degrees C lower and slip 6-fold faster. We interpret results in terms of base stacking, by relating melting temperature to standard enthalpy changes for doublets of base pairs and mispairs, considering enthalpy-entropy compensation.     

Srs2 helicase of Saccharomyces cerevisiae selectively unwinds triplet repeat DNA

Trinucleotide repeat expansions are the mutational cause of at least 15 genetic diseases. In vitro, single-stranded triplet repeat DNA forms highly stable hairpins, depending on repeat sequence, and a strong correlation exists between hairpin-forming ability and the risk of expansion in vivo. Hairpins are viewed, therefore, as likely mutagenic precursors to expansions. If a helicase unwinds the hairpin, it would be less likely to expand. Previous work indicated that yeast Srs2 DNA helicase selectively blocks expansions in vivo (Bhattacharyya, S., and Lahue, R. S. (2004) Mol. Cell. Biol. 24, 7324-7330). For example, srs2 mutants, including an ATPase-defective point mutant, exhibit substantially higher expansion rates than wild type controls. In contrast, mutation of another helicase gene, SGS1, had little effect on expansion rates. These findings prompted the idea that Srs2 might selectively unwind triplet repeat hairpins. In this study, DNA helicase assays were performed with purified Srs2, Sgs1, and Escherichia coli UvrD (DNA helicase II). Srs2 shows substantially faster unwinding than Sgs1 or UvrD on partial duplex substrates containing (CTG) x (CTG) sequences, provided that Srs2 encounters the triplet repeat DNA immediately on entering the duplex. Srs2 was also faster at unwinding (CAG) x (CAG)- and (CCG) x (CCG)-containing substrates and an intramolecular (CTG) x (CTG) hairpin. In contrast, all three enzymes unwind about equally well control substrates with either Watson-Crick base pairs or mismatched substrates with non-CNG repeats. Overall, the selective unwinding activity of Srs2 on triplet repeat hairpin DNA helps explain the genetic evidence that Srs2, not the RecQ homolog Sgs1, is a preferred helicase for preventing expansions.     

Energetic coupling between clustered lesions modulated by intervening triplet repeat bulge loops: Allosteric implications for DNA repair and triplet repeat expansion

Clusters of closely spaced oxidative DNA lesions present challenges to the cellular repair machinery. When located in opposing strands, base excision repair (BER) of such lesions can lead to double strand DNA breaks (DSB). Activation of BER and DSB repair pathways has been implicated in inducing enhanced expansion of triplet repeat sequences. We show here that energy coupling between distal lesions (8oxodG and/or abasic sites) in opposing DNA strands can be modulated by a triplet repeat bulge loop located between the lesion sites. We find this modulation to be dependent on the identity of the lesions (8oxodG vs. abasic site) and the positions of the lesions (upstream vs. downstream) relative to the intervening bulge loop domain. We discuss how such bulge loop‐mediated lesion crosstalk might influence repair processes, while favoring DNA expansion, the genotype of triplet repeat diseases. © 2009 Wiley Periodicals, Inc. Biopolymers 93: 355–369, 2010. This article was originally published online as an acceptedpreprint. The “Published Online” date corresponds to the preprint version. You can reqest a copy of the preprint byemailing the Biopolymers editorial office at biopolymers@wiley.com     

High-speed electrophoretic separation of DNA fragments using a short capillary

Capillary electrophoresis using a replaceable gel buffer was applied to the separation of DNA fragments. A short effective length capillary (1–2 cm) at low electric field allowed the separation of a 20–1000 bp ladder in 1 min. Although similar separation speed was achieved with a longer capillary at high field, the resolution of larger fragments was degraded. The short effective length capillaries were able to separate the wildtype and mutant PCR products of the TGF-β₁ gene in under 45 s.     

Stimulation on DNA triplet repeat strand slippage synthesis by the designed spirocycles

The designed simpler chiral spirocyclic helical compounds that mimic the molecular architecture of the DNA bulge binder NCSi-gb have been prepared. It has been found that the synthesized spirocyclic compounds have strong stimulation effect on DNA slippage synthesis. Their stimulation activities on DNA strand slippage suggest that they may bind to or induce the formation of a non Watson-Crick structure during in vitro replication of DNA triplet repeats.     

Mouse models of triplet repeat diseases

Triplet repeat expansions were first discovered in 1991 and since then have been found to be the mutation underlying a range of neurodegenerative, neuromuscular, and cognitive disorders including fragile X syndrome, myotonic dystrophy, Friedreich's ataxia, and the polyglutamine disorders that include Huntington's disease. The repeats exert their detrimental effects through different molecular mechanisms dependent on whether they are located in coding or noncoding regions of the gene in question. During the past 10 yr, a wide range of strategies have been used to successfully establish mouse models for all of these disorders. This review presents an overview of these mouse models, discusses the insights into the molecular pathogenesis of these disorders that have been gained from their analysis and the strategies that are being used to uncover novel therapeutic options.     

Impact of bulge loop size on DNA triplet repeat domains: Implications for DNA repair and expansion

Repetitive DNA sequences exhibit complex structural and energy landscapes, populated by metastable, noncanonical states, that favor expansion and deletion events correlated with disease phenotypes. To probe the origins of such genotype–phenotype linkages, we report the impact of sequence and repeat number on properties of (CNG) repeat bulge loops. We find the stability of duplexes with a repeat bulge loop is controlled by two opposing effects; a loop junction‐dependent destabilization of the underlying double helix, and a self‐structure dependent stabilization of the repeat bulge loop. For small bulge loops, destabilization of the underlying double helix overwhelms any favorable contribution from loop self‐structure. As bulge loop size increases, the stabilizing loop structure contribution dominates. The role of sequence on repeat loop stability can be understood in terms of its impact on the opposing influences of junction formation and loop structure. The nature of the bulge loop affects the thermodynamics of these two contributions differently, resulting in unique differences in repeat size‐dependent minima in the overall enthalpy, entropy, and free energy changes. Our results define factors that control repeat bulge loop formation; knowledge required to understand how this helix imperfection is linked to DNA expansion, deletion, and disease phenotypes. © 2013 Wiley Periodicals, Inc. Biopolymers 101: 1–12, 2014.     

Unusual behavior exhibited by multistranded guanine-rich DNA complexes

The structural properties of oligonucleotides containing two different types of G-rich sequences at the 3′-ends were compared. It is shown that oligonucleotides with uninterrupted runs of guanine residues at the 3′-end, e.g., d(T₁₅G₁₂), form multistranded structures stabilized by guanine-guanine interactions. The chemical and physical properties of these complexes differ from those of the complexes formed by oligonucleotides with telomere-like sequences, e.g., d(T₁₅G₄T₂G₄). In methylation protection and methylation interference experiments, we found all the guanines in complexes formed by d(T₁₅G₁₅) and d(T₁₅G₁₂) to be accessible to methylation. Furthermore, the methylated monomers retain the ability to polymerize. This contrasts with the inaccessibility of the guanines in d(T₁₅G₄T₂G₄) to methylation and the inability of the methylated monomer to form supramolecular structures. The stoichiometry of the complexes arising from the two types of oligonucleotides also differs. The complexes formed by d(T₁₅G₁₅) consist of consecutive integer numbers of DNA strands, whereas complexes formed by telomere-like oligonucleotides contain 1, 2, 4, or multiples of four strands. Magnesium ions favor formation of high molecular weight complexes by d(T₁₅G₁₅) and d(T₁₅G₁₂), but not by d(T₁₅G₄T₂G₄). The d(T₁₅G₁₅) and d(T₁₅G₁₂) complexes have very high thermal stability compared with telomeric complexes. However, at low temperatures, the thymine bases within the telomeric motif, TTGGGGTTGGGG, appear to allow for the formation of stable high-molecular weight species with a longer nonguanine portion. © 1998 John Wiley & Sons, Inc. Biopoly 45: 427–434, 1998     

Therapeutics development for triplet repeat expansion diseases

The underlying genetic mutations for many inherited neurodegenerative disorders have been identified in recent years. One frequent type of mutation is trinucleotide repeat expansion. Depending on the location of the repeat expansion, the mutation might result in a loss of function of the disease gene, a toxic gain of function or both. Disease gene identification has led to the development of model systems for investigating disease mechanisms and evaluating treatments. Examination of experimental findings reveals similarities in disease mechanisms as well as possibilities for treatment.     

Genetic instabilities of triplet repeat sequences by recombination

The expansion of triplet repeat sequences is an initial step in the disease etiology of a number of hereditary neurological disorders in humans. Diseases such as myotonic dystrophy, Huntington's, several spinocerebellar ataxias, fragile X syndrome, and Friedreich's ataxia are caused by the expansions of CTG.CAG, CGG.CCG, or GAA.TTC repeats. The mechanisms of the expansion process have been investigated intensely in E. coli, yeast, transgenic mice, mammalian cell culture, and in human clinical cases. Whereas studies from 1994-1999 have implicated DNA replication and repair at the paused synthesis sites due to the unusual conformations of the triplet repeat sequences, recent work has shown that homologous recombination (gene conversion) is a powerful mechanism for generating massive expansions, in addition to, or in concert with, replication and repair.     

Influence of sequence context and length on the structure and stability of triplet repeat DNA oligomers

Genetic expansion diseases have been linked to the properties of triplet repeat DNA sequences during replication. The most common triplet repeats associated with such diseases are CAG, CCG, CGG, and CTG. It has been suggested that gene expansion occurs as a result of hairpin formation of long stretches of these sequences on the leading daughter strand synthesized during DNA replication [Gellibolian, R., Bacolla, A., and Wells, R. D. (1997) J. Biol. Chem. 272, 16793-7]. To test the biophysical basis for this model, oligonucleotides of general sequence (CNG)(n), where N = A, C, G, or T and n = 4, 5, 10, 15, or 25, were synthesized and characterized by circular dichroism (CD) spectropolarimetry, optical melting studies, and differential scanning calorimetry (DSC). The goal of these studies was to evaluate the influence of sequence context and oligomer length on their secondary structures and stabilities. The results indicate that all single oligomers, even those as short as 12 nucleotides, form stable hairpin structures at 25 degrees C. Such hairpins are characterized by the presence of N:N mismatched base pairs sandwiched between G:C base pairs in the stems and loops of three to four unpaired bases. Thermodynamic analysis of these structures reveals that their stabilities are influenced by both the sequence of the particular oligomer and its length. Specifically, the stability order of CGG > CTG > CAG > CCG was observed. In addition, longer oligomers were found to be more stable than shorter oligomers of the same sequence. However, a stability plateau above 45 nucleotides suggests that the length dependence reaches a maximum value where the stability of the G:C base pairs can no longer compensate the instability of the N:N mismatches in the stems of the hairpins. The results are discussed in terms of the above model proposed for gene expansion.     

Detection of triplet repeat sequences in the double-stranded DNA using pyrene-functionalized pyrrole-imidazole polyamides with rigid linkers

Methods for sequence-specific detection in double-stranded DNA (dsDNA) are becoming increasingly useful and important as diagnostic and imaging tools. Recently, we designed and synthesized pyrrole (Py)-imidazole (Im) polyamides possessing two pyrene moieties, 1, which showed an increased excimer emission in the presence of (CAG)(12)-containing oligodeoxynucleotides (ODN) 1 and 2. In this study, we synthesized bis-pyrenyl Py-Im polyamides with rigid linkers 2, 3, and 4 to improve their fluorescence properties. Among the conjugates, 2 showed a marked increase in excimer emission, which was dependent on the concentration of the target ODN and the number of CAG repeats in the dsDNA. Unlike conjugate 1, which has flexible linkers, the excimer emission intensity of 2 was retained at over 85%, even after 4h. Py-Im polyamides have the potential to be important diagnostic molecules for detecting genetic differences between individuals.     

Examining the potential role of DNA polymerases eta and zeta in triplet repeat instability in yeast

Triplet repeats undergo frequent mutations in human families afflicted with certain neurodegenerative diseases and also in model organisms. Although the molecular mechanisms of triplet repeat instability are still being identified, it is likely that aberrant DNA synthesis plays an important role. Many DNA polymerases stall at triplet repeat sequences, probably due to the adoption of unusual DNA secondary structures. One possible mechanism to explain triplet repeat contractions is that a triplet repeat hairpin on the template strand inhibits replicative polymerases and that one or more bypass polymerases are recruited for synthesis past the hairpin. If the translesion synthesis is mutagenic, contractions can be generated. To address this possibility, Saccharomyces cerevisiae strains lacking either pol zeta (rev7), pol eta (rad30), or both were tested for trinucleotide repeat (TNR) contractions using three separate, sensitive genetic assays. If these bypass polymerases are important for mutagenesis, then the mutants should show a reduction in the contraction rate. Two genetic tests for triplet repeat contractions showed no significant change for the mutants compared to wild type. A third assay showed a five-fold reduction in contraction rates due to pol eta ablation. Despite this modest decrease, the overall contraction rate was still high, indicating that many deletions still occur in the absence of both polymerases. Expansion rates were also unaffected in the mutant strains. These results indicate that, in yeast, pol eta and pol zeta most likely have little role in triplet repeat mutagenesis.     

Hairpin formation in Friedreich's ataxia triplet repeat expansion

Triplet repeat tracts occur throughout the human genome. Expansions of a (GAA)(n)/(TTC)(n) repeat tract during its transmission from parent to child are tightly associated with the occurrence of Friedreich's ataxia. Evidence supports DNA slippage during DNA replication as the cause of the expansions. DNA slippage results in single-stranded expansion intermediates. Evidence has accumulated that predicts that hairpin structures protect from DNA repair the expansion intermediates of all of the disease-associated repeats except for those of Friedreich's ataxia. How the latter repeat expansions avoid repair remains a mystery because (GAA)(n) and (TTC)(n) repeats are reported not to self-anneal. To characterize the Friedreich's ataxia intermediates, we generated massive expansions of (GAA)(n) and (TTC)(n) during DNA replication in vitro using human polymerase beta and the Klenow fragment of Escherichia coli polymerase I. Electron microscopy, endonuclease cleavage, and DNA sequencing of the expansion products demonstrate, for the first time, the occurrence of large and growing (GAA)(n) and (TTC)(n) hairpins during DNA synthesis. The results provide unifying evidence that predicts that hairpin formation during DNA synthesis mediates all of the disease-associated, triplet repeat expansions.     

Evolution of a triplet repeat in a conifer.

The opportunity to trace the evolution of a triplet repeat is rare, especially for seed-plant lineages with a well-defined fossil record. Microsatellite PtTX2133 sequences from 18 species in 2 conifer genera were used to calibrate the birth of a CAGn repeat, from its protomicrosatellite origins to its repeat expansion. Birth occurred in the hard-pine genome ~ 136 million years ago, or 14 million generations ago, then expanded as a polymorphic triplet repeat 136-100 million years before a major North American vicariance event. Calibration of the triplet-repeat birth and expansion is supported by the shared allelic lineages among Old and New World hard pines and the shared alleles solely among North American diploxylon or hard pines. Five CAGn repeat units appeared to be the expansion threshold for Old and New World diploxylon pines. Haploxylon pine species worldwide did not undergo birth and repeat expansion, remaining monomorphic, with a single imperfect 198-bp allele. A sister genus, Picea, had only a region of cryptic simplicity, preceding a proto-microsatellite region. The polymorphic triplet repeat in hard pines is older than some long-lived microsatellites reported for reptiles, yet younger than those reported for insects. Some cautionary points are raised about phylogenetic applications for this long-lived microsatellite.