(CGA)(4): parallel, anti-parallel, right-handed and left-handed homoduplexes of a trinucleotide repeat DNA.

Conformational properties of microsatellite DNA regions are the probable reason of their expansions in genomes which lead to serious genetic diseases in some cases. Using CD spectroscopy, UV absorption spectroscopy and polyacrylamide gel electrophoresis, we study in this paper conformational properties of (CGA)(4) and compare them with those of (CAG)(4) - a related repeat, connected with Huntington's disease. We show that (CGA)(4) can adopt several distinct conformations in solution. Around neutral pH it forms a parallel-stranded homoduplex containing C(+).C, G.G, and A.A base pairs. Under the same conditions (CAG)(4) forms a hairpin. At slightly alkaline pH values and low ionic strength, (CGA)(4) also folded into a hairpin which transformed into a bimolecular anti-parallel homoduplex at increasing salt concentrations. The duplex easily isomerized into left-handed Z-DNA, implying that the mismatched adenines between G.C pairs facilitate rather than hinder the B-Z transition. No similar changes took place with (CAG)(4). Thus, the conformational repertoire of (CGA)(4) includes parallel, anti-parallel, right-handed, and left-handed homoduplexes. In contrast, (CAG)(4) invariably adopts only a single conformation, namely the very stable hairpin.     

Dimerization of the guanine-adenine repeat strands of DNA.

Jovin and co-workers have demonstrated that DNA strands containing guanine-adenine repeats generate a parallel-stranded homoduplex. Here we propose that the homoduplex is a dimer of the ordered single strand discovered by Fresco and co-workers at acid pH. The Fresco single strand is shown here to be stabilized in aqueous ethanol where adenine is not protonated. Furthermore, we demonstrate that the strands dimerize at higher salt concentrations without significantly changing their conformation, so that the dimerization is non-cooperative. Hence, the Jovin homoduplex can form through a non-cooperative dimerization of two cooperatively melting single strands. The available data indicate that the guanines stabilize the Fresco single strand whereas the adenines cause dimerization owing to their known intercalation or clustering tendency. The guanine-adenine repeat dimer seems to be a DNA analog of the leucine zipper causing dimerization of proteins.     

Conformational properties of DNA containing (CCA)n and (TGG)n trinucleotide repeats

We have used CD spectroscopy, polyacrylamide gel electrophoresis, and UV absorption spectroscopy to study conformational properties of DNA fragments containing (CCA)n and (TGG)n repeats, which are the most length-polymorphic microsatellite sequences of the human genome. The (CCA)n fragments are random single strands at neutral and alkaline pH but they fold into intramolecular intercalated cytosine tetraplexes at mildly acid pH values. More acid values stabilize intermolecular tetraplex formation. The behavior of (TGG)n repeats is more complex. They form hairpins or antiparallel homoduplexes in low salt solutions which, however, are transformed into parallel-stranded guanine tetraplexes at physiological KCl concentrations. Their molecularity depends on the repeat number: (TGG)4 associates into an octameric complex, (TGG)8 forms tetramolecular complexes. (TGG)n with odd repeat numbers (5, 7, and 9) generate bimolecular and tetramolecular tetraplexes. The only (TGG)7 folds into an intramolecular tetraplex at low KCl concentrations, which is antiparallel-stranded. Moreover, the (TGG)(n) fragments provide various mutually slipped conformers whose population increases with salt concentration and with the increasing repeat number. However, the self-structures of both strands disappear in the presence of the complementary strand because both (TGG)n and (CCA)n prefer to associate into the classical heteroduplex. We suppose that the extreme conformational variability of the DNA strands stands behind the length polymorphism which the (CCA)n/(TGG)n repeats exhibit in the human genome.     

Small-molecule ligand induces nucleotide flipping in (CAG)n trinucleotide repeats

DNA trinucleotide repeats, particularly CXG, are common within the human genome. However, expansion of trinucleotide repeats is associated with a number of disorders, including Huntington disease, spinobulbar muscular atrophy and spinocerebellar ataxia. In these cases, the repeat length is known to correlate with decreased age of onset and disease severity. Repeat expansion of (CAG)n, (CTG)n and (CGG)n trinucleotides may be related to the increased stability of alternative DNA hairpin structures consisting of CXG-CXG triads with X-X mismatches. Small-molecule ligands that selectively bound to CAG repeats could provide an important probe for determining repeat length and an important tool for investigating the in vivo repeat extension mechanism. Here we report that napthyridine-azaquinolone (NA, 1) is a ligand for CAG repeats and can be used as a diagnostic tool for determining repeat length. We show by NMR spectroscopy that binding of NA to CAG repeats induces the extrusion of a cytidine nucleotide from the DNA helix.     

Replication and expansion of trinucleotide repeats in yeast

The mechanisms of trinucleotide repeat expansions, underlying more than a dozen hereditary neurological disorders, are yet to be understood. Here we looked at the replication of (CGG)(n) x (CCG)(n) and (CAG)(n) x (CTG)(n) repeats and their propensity to expand in Saccharomyces cerevisiae. Using electrophoretic analysis of replication intermediates, we found that (CGG)(n) x (CCG)(n) repeats significantly attenuate replication fork progression. Replication inhibition for this sequence becomes evident at as few as approximately 10 repeats and reaches a maximal level at 30 to 40 repeats. This is the first direct demonstration of replication attenuation by a triplet repeat in a eukaryotic system in vivo. For (CAG)(n) x (CTG)(n) repeats, on the contrary, there is only a marginal replication inhibition even at 80 repeats. The propensity of trinucleotide repeats to expand was evaluated in a parallel genetic study. In wild-type cells, expansions of (CGG)(25) x (CCG)(25) and (CAG)(25) x (CTG)(25) repeat tracts occurred with similar low rates. A mutation in the large subunit of the replicative replication factor C complex (rfc1-1) increased the expansion rate for the (CGG)(25) repeat approximately 50-fold but had a much smaller effect on the expansion of the (CTG)(25) repeat. These data show dramatic sequence-specific expansion effects due to a mutation in the lagging strand DNA synthesis machinery. Together, the results of this study suggest that expansions are likely to result when the replication fork attempts to escape from the stall site.     

Trinucleotide repeats associated with human disease.

Triplet repeat expansion diseases (TREDs) are characterized by the coincidence of disease manifestation with amplification of d(CAG. CTG), d(CGG.CCG) or d(GAA.TTC) repeats contained within specific genes. Amplification of triplet repeats continues in offspring of affected individuals, which generally results in progressive severity of the disease and/or an earlier age of onset, phenomena clinically referred to as 'anticipation'. Recent biophysical and biochemical studies reveal that five of the six [d(CGG)n, d(CCG)n, (CAG)n, d(CTG)n and d(GAA)n] complementary sequences that are associated with human disease form stable hairpin structures. Although the triplet repeat sequences d(GAC)n and d(GTC)n also form hairpins, repeats of the double-stranded forms of these sequences are conspicuously absent from DNA sequence databases and are not anticipated to be associated with human disease. With the exception of d(GAG)n and d(GTG)n, the remaining triplet repeat sequences are unlikely to form hairpin structures at physiological salt and temperature. The details of hairpin structures containing trinucleotide repeats are summarized and discussed with respect to potential mechanisms of triplet repeat expansion and d(CGG.CCG) n methylation/demethylation.     

No evidence of expansion of CAG or GAA repeats in schizophrenia families and monozygotic twins

Many diseases caused by trinucleotide expansion exhibit increased severity and decreased age of onset (genetic anticipation) in successive generations. Apparent evidence of genetic anticipation in schizophrenia has led to a search for trinucleotide repeat expansions. We have used several techniques, including Southern blot hybridization, repeat expansion detection (RED) and locus-specific PCR to search for expanded CAG/CTG repeats in 12 families from the United Kingdom and 11 from Iceland that are multiplex for schizophrenia and demonstrate anticipation. The unstable DNA theory could also explain discordance of phenotype for schizophrenia in pairs of monozygotic twins, where the affected twin has a greater number of repeats than the unaffected twin. We used these techniques to look for evidence of different CAG/CTG repeat size in 27 pairs of monozygotic twins who are either concordant or discordant for schizophrenia. We have found no evidence of an increase in CAG/CTG repeat size for affected members in the families, or for the affected twins in the MZ twin sample. Southern hybridization and RED analysis were also performed for the twin and family samples to look for evidence of expansion of GAA/TTC repeats. However, no evidence of expansion was found in either sample. Whilst these results suggest that these repeats are not involved in the etiology of schizophrenia, the techniques used for detecting repeat expansions have limits to their sensitivity. The involvement of other trinucleotide repeats or other expandable repeat sequences cannot be ruled out. Received: 8 September 1997 / Accepted: 13 March 1998     

Anticipation and Instability of IT-15 (CAG)N Repeats in Parent-Offspring Pairs with Huntington Disease

Huntington disease (HD) is an autosomal dominant degenerative disorder caused by an expanded and unstable trinucleotide repeat (CAG)n in a gene (IT-15) on chromosome 4. HD exhibits genetic anticipation—earlier onset in successive generations within a pedigree. From a population-based clinical sample, we ascertained parent-offspring pairs with expanded alleles, to examine the intergenerational behavior of the trinucleotide repeat and its relationship to anticipation. We find that the change in repeat length with paternal transmission is significantly correlated with the change in age at onset between the father and offspring. When expanded triplet repeats of affected parents are separated by median repeat length, we find that the longer paternal and maternal repeats are both more unstable on transmission. However, unlike in paternal transmission, in which longer expanded repeats display greater net expansion than do shorter expanded repeats, in maternal transmission there is no mean change in repeat length for either longer or shorter expanded repeats. We also confirmed the inverse relationship between repeat length and age at onset, the higher frequency of juvenile-onset cases arising from paternal transmission, anticipation as a phenomenon of paternal transmission, and greater expansion of the trinucleotide repeat with paternal transmission. Stepwise multiple regression indicates that, in addition to repeat length of offspring, age at onset of affected parent and sex of affected parent contribute significantly to the variance in age at onset of the offspring. Thus, in addition to triplet repeat length, other factors, which could act as environmental factors, genetic factors, or both, contribute to age at onset. Our data establish that further expansion of paternal repeats within the affected range provides a biological basis of anticipation in HD.     

Conformational properties of DNA strands containing guanine-adenine and thymine-adenine repeats.

CD spectroscopy and PAGE were used to cooperatively analyze melting conformers of DNA strands containing GA and TA dinucleotide repeats. The 20mer (GA)10 formed a homoduplex in neutral solutions containing physiological concentrations of salts and this homoduplex was not destabilized even in the terminal (GA)3 hexamers of (GA)3(TA)4(GA)3, although the central (TA)4 portion of this oligonucleotide preserved the conformation adopted by (TA)10. This observation demonstrates that homoduplexes of alternating GA and TA sequences can co-exist in a single DNA molecule. Another 20mer, (GATA)5, adopted as a whole either the AT duplex, like (TA)10, or the GA duplex, like (GA)10, and switched between them reversibly. The concentration of salt controlled the conformational switching. Hence, guanine and thymine share significant properties regarding complementarity to adenine, while the TA and GA sequences can stack in at least two mutually compatible ways within the DNA duplexes analyzed here. These properties extend our knowledge of non-canonical structures of DNA.     

Intercalated cytosine motif and novel adenine clusters in the crystal structure of the Tetrahymena telomere.

The cytosine-rich strand of the Tetrahymena telomere consists of multiple repeats of sequence d(AACCCC). We have solved the crystal structure of the crystalline repeat sequence at 2.5 A resolution. The adenines form two different and previously unknown clusters (A clusters) in orthogonal directions with their counterparts from other strands, each containing a total of eight adenines. The clusters appear to be stable aggregates held together by base stacking and three different base-pairing modes. Two different types of cytosine tetraplexes are found in the crystal. Each four-stranded complex is composed of two intercalated parallel-stranded duplexes pointing in opposite directions, with hemiprotonated cytosine-cytosine (C.C+) base pairs. The outermost C.C+base pairs are from the 5'-end of each strand in one cytosine tetraplex and from the 3'-end of each strand in the other. The A clusters and the cytosine tetraplexes form two alternating stacking patterns, creating continuous base stacking in two perpendicular directions along the x - and z -axes. The adenine clusters could be organizational motifs for macromolecular RNA.     

Conformational properties of DNA dodecamers containing four tandem repeats of the CNG triplets.

We studied DNA dodecamers (CAG)4, (CCG)4, (CGG)4 and (CTG)4by CD spectroscopy and polyacrylamide gel electrophoresis. Each dodecamer adopted several ordered conformers which denatured in a cooperative way. Stability of the conformers depended on the dodecamer concentration, ionic strength, temperature and pH. The dodecamers, having a pyrimidine base in the triplet center, generated foldbacks at low ionic strength whose stem conformations were governed by the GC pairs. At high salt, (CCG)4 isomerized into a peculiar association of two strands. The association was also promoted by high oligonucleotide concentrations. No similar behavior was exhibited by (CTG)4. At low salt, (CGG)4 coexisted in two bimolecular conformers whose populations were strongly dependent on the ionic strength. In addition, (CGG)4 associated into a tetraplex at acidic pH. A tetraplex was even observed at neutral pH if the (CGG)4 concentration was sufficiently high. (CAG)4 was very stable in a monomolecular conformer similar to the known extremely stable foldback of the (GCGAAGC) heptamer. Nevertheless, even this very stable conformer disappeared if (CTG)4 was added to the solution of (CAG)4. Association of the complementary strands was also strongly preferred to the particular strand conformations by the other couple, (CCG)4 and (CGG)4.     

Towards a better understanding of the unusual conformations of the alternating guanine-adenine repeat strands of DNA

Alternating guanine-adenine strands of DNA are known to self-associate into a parallel-stranded homoduplex at neutral pH, fold into an ordered single-stranded structure at acid pH, and adopt yet another ordered single-stranded conformer in aqueous ethanol. The unusual conformers melt cooperatively and exhibit distinct circular dichroism spectra suggestive of a substantial conformational order, but their molecular structures are not known yet. Here, we have probed the molecular structures using guanine and adenine analogs lacking the N7 atom, and thus unable of Hoogsteen pairing, or those restrained in the less-frequent syn glycosidic orientation. The studies showed that the syn glycosidic orientation of dA residues promoted the neutral homoduplex, whereas the syn orientation of dG was incompatible with the homoduplex. In addition, Hoogsteen pairing of dA seemed to be a crucial property of the homoduplex whereas dG did not pair in this way. The situation was the same in both single-stranded conformers with the dG residues. On the other hand, the presence of N7 was important with dA but its syn geometry was not favorable. The present data can be used as restraints to model the unusual molecular structures of the alternating guanine-adenine strands of DNA.     

Genetic anticipation in Portuguese kindreds with familial amyloidotic polyneuropathy is unlikely to be caused by triplet repeat expansions

Familial amyloidotic polyneuropathy (FAP) is a lethal autosomal dominant type of amyloidosis resulting from the deposition of transthyretin (ATTR) variants in the peripheral and autonomic nervous systems. ATTR V30M-associated FAP exhibits marked genetic anticipation in some families, with clinical symptoms developing at an earlier age in successive generations. The genetic basis of this phenomenon in FAP is unknown. Anticipation has been associated with the dynamic expansion of trinucleotide repeats in several neurodegenerative disorders, such as Huntington disease, myotonic dystrophy, and fragile X syndrome. We have used the repeat expansion detection (RED) assay to screen affected members of Portuguese FAP kindreds for expansion of any of the ten possible trinucleotide repeats. Nine generational pairs with differences in their age of onset greater than 12 years and a control pair with identical ages of onset were tested. No major differences were found in the lengths of the ten trinucleotide repeats analyzed. The distribution of the maximal repeat sizes was consistent with reported studies in unrelated individuals with no known genetic disease. The present data do not support a role for trinucleotide repeat expansions as the molecular mechanism underlying anticipation in Portuguese FAP. Received: 13 December 1998 / Accepted: 23 March 1999     

三核苷酸重复序列失稳定机制:重复序列形成non-B二级结构的必要性和细胞反式作用因子的作用

与三核苷酸重复序列CAG.CTG、CGG·CCG和GAA·TTC扩增和缺失有关的分子机制尚不能得到清楚的阐释.体外研究表明,上述疾病相关的重复序列可以在体外形成non-B二级结构,并介导重复序列扩增.然而,迄今为止,类似的观察尚未在体内研究过程中得以实现.利用模型生物大肠杆菌和酵母等进行的有关研究并不能模拟三核苷酸重复序列的扩增,这暗示三核苷酸重复序列的体内扩增可能与重复序列形成non-B二级结构关联性并不大.尽管理论上较长的三核苷酸重复序列可以在复制和后复制过程中较易形成non-B DNA二级结构,但这样的二级结构倾向于导致重复序列出现"脆性",而不是扩增.事实上,患者所具有的三核苷酸重复序列扩增并非一定需要通过non-B二级结构的介导,这些重复序列的扩增是可以通过一种RNA转录诱导的局部DNA重复序列的复制和其后的DNA重排得以发生.     

Novel eGZ-motif formed by regularly extruded guanine bases in a left-handed Z-DNA helix as a major motif behind CGG trinucleotide repeats

The expansion of d(CGG) trinucleotide repeats (TRs) lies behind several important neurodegenerative diseases. Atypical DNA secondary structures have been shown to trigger TR expansion: their characterization is important for a molecular understanding of TR disease. CD spectroscopy experiments in the last decade have unequivocally demonstrated that CGG runs adopt a left-handed Z-DNA conformation, whose features remain uncertain because it entails accommodating GG mismatches. In order to find this missing motif, we have carried out molecular dynamics (MD) simulations to explore all the possible Z-DNA helices that potentially form after the transition from B- to Z-DNA. Such helices combine either CpG or GpC Watson-Crick steps in Z-DNA form with GG-mismatch conformations set as either intrahelical or extrahelical; and participating in BZ or ZZ junctions or in alternately extruded conformations. Characterization of the stability and structural features (especially overall left-handedness, higher-temperature and steered MD simulations) identified two novel Z-DNA helices: the most stable one displays alternately extruded Gs, and is followed by a helix with symmetrically extruded ZZ junctions. The G-extrusion favors a seamless stacking of the Watson-Crick base pairs; extruded Gs favor syn conformations and display hydrogen-bonding and stacking interactions. Such conformations could have the potential to hijack the MMR complex, thus triggering further expansion.     

Progressive myoclonus epilepsy [EPM1] repeat d(CCCCGCCCCGCG)n forms folded hairpin structures at physiological pH.

The secondary structure of DNA has been shown to be an important component in the mechanism of expansion of the trinucleotide repeats that are associated with many neurodegenerative disorders. Recently, expansion of a dodecamer repeat, (CCCCGCCCCGCG)n upstream of cystatin B gene has been shown to be the most common mutation associated with Progressive Myoclonus Epilepsy (EPM1) of Unverricht-Lundborg type. We have investigated structure of oligonucleotides containing one, two and three copies of the EPM1 repeat sequences at physiological pH. CD spectra and anomalous faster gel electrophoretic mobilty indicates formation of intramolecularly folded structures that are formed independent of concentration. Hydroxylamine probing allowed us to identify the C residues that are involved in C.G base pairing. P1 nuclease studies elucidated the presence of unpaired regions in the folded back structures. UV melting studies show biphasic melting curves for the oligonucleotides containing two and three EPM1 repeats. Our data suggests multiple hairpin structures for two and three repeat containing oligonucleotides. In this paper we show that oligonucleotides containing EPM1 repeat adopt secondary structures that may facilitate strand slippage thereby causing the expansion.     

Sequence organization of the rat genome by electron microscopy.

The size and arrangement of repetitive and inverted repeat (foldback) sequences in rat DNA were studied by visualization of hybrid and heteroduplex structures in the electron microscope. The self-reassociation of repetitive sequence-bearing DNA strands often results in the formation of four-ended "H" structures, whose duplex regions equal the repetitive sequence length and can be measured in the electron microscope. In this way, it was determined that the average size of the class of numerous short repetitive sequences is 0.40 +/- 0.15 kbp. Heteroduplex structures were prepared between long whole DNA single strands and short repeat-sequence-bearing strands. The analysis of these structures confirms that the size of the repetitive sequences in 0.4 kbp on average. Length measurements between adjacent duplexes show that the average spacing between two interspersed repeats is at least 1.5-1.8 kbp. By examining 29.4-kbp single strands after brief renaturation, the size and distribution of foldback sequences were determined. There are 1.9 X 10(5) foldback apirs per rat genome, spaced an average of 9.7 kbp apart according to our measurement. Repetitive, inverted repeat and unique sequences are interspersed with each other in at least half the genome.     

The segment inversion site of herpes simplex virus type 1 adopts a novel DNA structure

The 12-base pair (bp) tandem direct repeat sequences (DR2) at the joint region (a sequence) of herpes simplex virus type 1 (strain F) adopt a new type of DNA conformation under the influence of negative supercoiling. The novel conformation is dependent on the number of the DR2 repeats; the 19 mer (228 bp total) and the 14 mer (168 bp) readily form the alternate structure whereas pentamer, trimer, and dimer repeats show somewhat different properties. S1 and P1 nuclease studies reveal that the new conformation has a major structural aberration at its center and conformational periodicities which are not identical on the complementary strands. Also, the effect of salt and pH, the location of reaction with bromo- and chloroacetaldehyde, the type of sequence (direct repeat) involved, and the nature and extent of supercoil-induced relaxations demonstrate that this structure differs from previously recognized conformations including left-handed Z helices, cruciforms, bent DNA, and slipped structures. We propose the existence of a novel conformation, anisomorphic DNA, with different structures on the complementary strands which elicit a structural aberration at the physical center of the tandem sequences. Since the oligopurine X oligopyrimidine sequence may be inherently inflexible, this supercoil-induced structural change and the physical stress on these inserts in recombinant plasmids tend to deform (crack) the DR2 sequences at their centers. Possible roles for anisomorphic DNA in the functions of this segment of intense biological activity are proposed.