Dinucleotide repeat expansion catalyzed by bacteriophage T4 DNA polymerase in vitro

DNA replication normally occurs with high fidelity, but certain "slippery" regions of DNA with tracts of mono-, di-, and trinucleotide repeats are frequently mutation hot spots. We have developed an in vitro assay to study the mechanism of dinucleotide repeat expansion. The primer-template resembles a base excision repair substrate with a single nucleotide gap centered opposite a tract of nine CA repeats; nonrepeat sequences flank the dinucleotide repeats. DNA polymerases are expected to repair the gap, but further extension is possible if the DNA polymerase can displace the downstream oligonucleotide. We report here that the wild type bacteriophage T4 DNA polymerase carries out gap and strand displacement replication and also catalyzes a dinucleotide expansion reaction. Repeat expansion was not detected for an exonuclease-deficient T4 DNA polymerase or for Escherichia coli DNA polymerase I. The dinucleotide repeat expansion reaction catalyzed by wild type T4 DNA polymerase required a downstream oligonucleotide to "stall" replication and 3' --> 5' exonuclease activity to remove the 3'-nonrepeat sequence adjacent to the repeat tract in the template strand. These results suggest that dinucleotide repeat expansion may be stimulated in vivo during DNA repair or during processing of Okazaki fragments.     

Effects of temperature, Mg2+ concentration and mismatches on triplet-repeat expansion during DNA replication in vitro.

The human genome contains many simple tandem repeats that are widely dispersed and highly polymorphic. At least one group of simple tandem repeats, the DNA trinucleotide repeats, can dramaticallyexpand in size during transmission from one generation to the next to cause disease by a process known as dynamic mutation. We investigated the ability of trinucleotide repeats AAT and CAG to expand in size during DNA replication using a minimal in vitro system composed of the repeat tract, with and without unique flanking sequences, and DNA polymerase. Varying Mg2+concentration and temperature gave dramatic expansions of repeat size during DNA replication in vitro. Expansions of up to 1000-fold were observed. Mismatches partially stabilized the repeat tracts against expansion. Expansions were only detected when the primer was complementary to the repeat tract rather than the flanking sequence. The results imply that cellular environment and whether the growing strand contains a nick or gap are important factors for the expansion process in vivo.     

Coordinated Processing of 3′ Slipped (CAG)n/(CTG)n Hairpins by DNA Polymerases β and δ Preferentially Induces Repeat Expansions

Expansion of CAG/CTG trinucleotide repeats causes certain familial neurological disorders. Hairpin formation in the nascent strand during DNA synthesis is considered a major path for CAG/CTG repeat expansion. However, the underlying mechanism is unclear. We show here that removal or retention of a nascent strand hairpin during DNA synthesis depends on hairpin structures and types of DNA polymerases. Polymerase (pol) δ alone removes the 3′-slipped hairpin using its 3′-5′ proofreading activity when the hairpin contains no immediate 3′ complementary sequences. However, in the presence of pol β, pol δ preferentially facilitates hairpin retention regardless of hairpin structures. In this reaction, pol β incorporates several nucleotides to the hairpin 3′-end, which serves as an effective primer for the continuous DNA synthesis by pol δ, thereby leading to hairpin retention and repeat expansion. These findings strongly suggest that coordinated processing of 3′-slipped (CAG)_n/(CTG)_n hairpins by polymerases δ and β on during DNA synthesis induces CAG/CTG repeat expansions.     

Mechanism of in vitro expansion of long DNA repeats: effect of temperature, repeat length, repeat sequence, and DNA polymerases.

Studies of sequence repeat expansions from duplexes consisting of DNA repeat sequences greater than three bases are currently lacking. These studies are needed in order to gain a better understanding of DNA expansions in general and as a first step in understanding expansions of longer sequence repeats that have been implicated in human diseases. We have undertaken an in vitro study of tetranucleotide, hexanucleotide, and octanucleotide repeat expansions from short DNA duplexes using Taq DNA polymerase. Expansions of hexanucleotide repeats were also studied with the Klenow fragment of DNA polymerase I and with T4 DNA polymerase. Studies with Taq DNA polymerase show that expansions occur more readily as the length of the repeat sequence decreases but are generally more efficient at reaction temperatures closer to the melting point of the starting duplex. A mechanism for the observed expansions with Taq DNA polymerase is proposed that does not invoke strand slippage or DNA structure. Studies at 37 degrees C with Klenow pol I and T4 DNA polymerase indicate that the template-switching and/or strand-displacement activities of the polymerases used can play a major role in the apparent in vitro expansions of short repetitive DNA duplexes.     

Taq DNA polymerase slippage mutation rates measured by PCR and quasi-likelihood analysis: (CA/GT)n and (A/T)n microsatellites

During microsatellite polymerase chain reaction (PCR), insertion–deletion mutations produce stutter products differing from the original template by multiples of the repeat unit length. We analyzed the PCR slippage products of (CA)_n and (A)_n tracts cloned in a pUC18 vector. Repeat numbers varied from two to 14 (CA)_n and four to 12 (A)_n. Data was generated on approximately 10 single molecules for each clone type using two rounds of nested PCR. The size and peak areas of the products were obtained by capillary electrophoresis. A quasi- likelihood approach to the analysis of the data estimated the mutation rate/repeat/PCR cycle. The rate for (CA)_n tracts was 3.6 × 10^–3 with contractions 14 times greater than expansions. For (A)_n tracts the rate was 1.5 × 10^–2 and contractions outnumbered expansions by 5-fold. The threshold for detecting ‘stutter’ products was computed to be four repeats for (CA)_n and eight repeats for (A)_n or ~8 bp in both cases. A comparison was made between the computationally and experimentally derived threshold values. The threshold and expansion to contraction ratios are explained on the basis of the active site structure of Taq DNA polymerase and models of the energetics of slippage events, respectively.     

Trinucleotide repeat expansions catalyzed by human cell-free extracts

Trinucleotide repeat expansions cause 17 heritable human neurological disorders. In some diseases, somatic expansions occur in non-proliferating tissues such as brain where DNA replication is limited. This finding stimulated significant interest in replication-independent expansion mechanisms. Aberrant DNA repair is a likely source, based in part on mouse studies showing that somatic expansions are provoked by the DNA repair protein MutSβ (Msh2-Msh3 complex). Biochemical studies to date used cell-free extracts or purified DNA repair proteins to yield partial reactions at triplet repeats. The findings included expansions on one strand but not the other, or processing of DNA hairpin structures thought to be important intermediates in the expansion process. However, it has been difficult to recapitulate complete expansions in vitro, and the biochemical role of MutSβ remains controversial. Here, we use a novel in vitro assay to show that human cell-free extracts catalyze expansions and contractions of trinucleotide repeats without the requirement for DNA replication. The extract promotes a size range of expansions that is similar to certain diseases, and triplet repeat length and sequence govern expansions in vitro as in vivo. MutSβ stimulates expansions in the extract, consistent with aberrant repair of endogenous DNA damage as a source of expansions. Overall, this biochemical system retains the key characteristics of somatic expansions in humans and mice, suggesting that this important mutagenic process can be restored in the test tube.     

甲肝病毒减毒株(H2)RNA的全长RT-PCR扩增

通过RT-PCR技术扩增了甲肝病毒减毒株(H₂)全长RNA,并对长片段RT-PCR扩增进行了方法学上的探讨.采用抗血清特异沉淀病毒;盐酸胍-酸性酚、氯仿一步法分离纯化病毒RNA,可得到高质量的RNA样品;以此RNA为模板,在无RNA酶的逆转录酶作用下,合成单链cDNA;继续以此cDNA为模板,利用32 mer寡核苷酸引物, 在Taq和Deep Vent DNA多聚酶的作用下进行PCR扩增,得到7.4 kb的扩增产物.     

A small molecule regulates hairpin structures in d(CGG) trinucleotide repeats

Unusual expansion of trinucleotide repeats has been identified as a common mechanism of hereditary neurodegenerative diseases. Although the actual mechanism of repeat expansion remains uncertain, trinucleotide repeat instability may be related to the increased stability of an alternative DNA hairpin structure formed in the repeat sequences. Here we report that a synthetic ligand naphthyridine carbamate dimer (NCD) selectively bound to and stabilized an intra-stranded hairpin structure in CGG repeat sequences. The NCD-CGG hairpin complex was a stable structure that efficiently interfered with DNA replication by Taq DNA polymerase. Considering the sequence preference of NCD, the use of NCD would be valuable to investigate the genetic instabilities of CGG/CCG repeat sequences in human genomes.     

The fragile X chromosome (GCC) repeat folds into a DNA tetraplex at neutral pH

UV absorption and CD spectroscopy, along with polyacrylamide gel electrophoresis, were used to study conformational properties of DNA fragments containing the trinucleotide repeat (GCC)_n (n = 4, 8 or 16), whose expansion is correlated with the fragile X chromosome syndrome. We have found that the conformational spectrum of the (GCC)_n strand is wider than has been shown so far. (GCC)_n strands adopt the hairpin described in the literature under a wide range of salt concentrations, but only at alkaline (>7.5) pH values. However, at neutral and slightly acid pH (GCC)₄ and (GCC)₈ strands homodimerize. Our data suggest that the homodimer is a bimolecular tetraplex formed by two parallel-oriented hairpins held together by hemi-protonated intermolecular C·C⁺ pairs. The (GCC)₁₆ strand forms the same tetraplex intramolecularly. We further show that below pH 5 (GCC)_n strands generate intercalated cytosine tetraplexes, whose molecularity depends on DNA strand length. They are tetramolecular with (GCC)₄, bimolecular with (GCC)₈ and monomolecular with (GCC)₁₆. i-Tetraplex formation is a complex and slow process. The neutral tetraplex, on the other hand, arises with fast kinetics under physiological conditions. Thus it is a conformational alternative of the (GCC)_n strand duplex with a complementary (GGC)_n strand.     

In vitro (CTG)*(CAG) expansions and deletions by human cell extracts

The mechanism of disease-associated (CTG)*(CAG) expansion may involve DNA replication slippage, replication direction, Okazaki fragment processing, recombination, or repair. A length-dependent bias for expansions is observed in humans affected by a trinucleotide repeat-associated disease. We developed an assay to test the effect of replication direction on (CTG)*(CAG) instabilities incurred during in vitro (SV40) DNA replication mediated by human cell extracts. This system recapitulates the bias for expansions observed in humans. Replication by HeLa cell extracts generated expansions and deletions that depended upon repeat tract length and the direction of replication. Templates with 79 repeats yielded predominantly expansions (CAG as lagging strand template) or predominantly deletions (CTG as lagging strand template). Templates containing 17 repeats were stable. Thus, replication direction determined the type of mutation. These results provide new insights into the orientation of replication effect upon repeat stability. This system will be useful in determining the contribution of specific human proteins to (CTG)*(CAG) expansions.     

Expansion of GAA trinucleotide repeats in mammals

We have previously shown that GAA trinucleotide repeats have undergone significant expansion in the human genome. Here we present the analysis of the length distribution of all 10 nonredundant trinucleotide repeat motifs in 20 complete eukaryotic genomes (6 mammalian, 2 nonmammalian vertebrates, 4 arthropods, 4 fungi, and 1 each of nematode, amoebozoa, alveolate, and plant), which showed that the abundance of large expansions of GAA trinucleotide repeats is specific to mammals. Analysis of human-chimpanzee-gorilla orthologs revealed that loci with large expansions are species-specific and have occurred after divergence from the common ancestor. PCR analysis of human controls revealed large expansions at multiple human (GAA)(30+) loci; nine loci showed expanded alleles containing >65 triplets, analogous to disease-causing expansions in Friedreich ataxia, including two that are in introns of genes of unknown function. The abundance of long GAA trinucleotide repeat tracts in mammalian genomes represents a significant mutation potential and source of interindividual variability.     

Stimulation of DNA strand slippage synthesis by a bulge binding synthetic agent

It has been postulated that bulged structures may be intermediates in the DNA strand slippage synthesis associated with the expansion of nucleotide repeats in various neurodegenerative diseases and cancer. To probe the possible role of bulged structures in this process, we have synthesized a wedge-shaped spirocyclic molecule, DDI (double-decker intercalator), on the basis of our earlier work with the bulge-specific derivative prepared from the enediyne antitumor antibiotic neocarzinostatin chromophore. Using a series of primers/templates containing nucleotide repeats [(AAT)(3)/(ATT)(5), (ATT)(3)/(AAT)(5), (CAG)(3)/(CTG)(5), (CA)(4)C/(GT)(7)G, (GT)(4)G/(CA)(7)C, T(9)/A(30), T(20)/A(30)] with the Klenow fragment of Escherichia coli DNA polymerase I, we find that DDI markedly enhances the formation of long DNA products, whose synthesis would require strand slippage to occur. DDI-induced slippage synthesis is more pronounced as the incubation proceeds and at limiting enzyme levels. The gel band pattern of the synthesized DNA products reflects the particular nucleotide repeat unit and is not altered by DDI. The lack of any drug effect on primer extension on M13 DNA and heteropolymeric 62-mer templates, where strand slippage is much less likely to occur, suggests that stimulation of slippage synthesis by DDI is not due to a direct effect on the enzyme. By contrast, other DNA-binding agents, such as ethidium bromide, distamycin, and doxorubicin, inhibit the formation of slippage-induced DNA products, but this block can be overcome by DDI, presumably by its destabilizing duplex DNA-binding sites for these other agents. We propose that DDI binds to or induces the formation of a bulge or related structure, which promotes DNA strand slippage and its consequent expansion of nucleotide repeats during replication by DNA polymerase I and that this action provides insight into the development of agents that interfere with nucleotide expansions found in various disease states.     

PCR片段测序和基因分型两种方法对Kennedy遗传病的诊断

X连锁脊延髓肌萎缩症（SBMA）或肯尼迪病是一种成年人发病的神经变性疾病,以肌无力与慢性、进行性肌萎缩为特征. 通过PCR片段测序和基因分型法准确检测雄激素受体（AR）基因CAG复制数目,兄弟俩（来自同一个中国家庭）被确诊为隐性遗传性SBMA. 为了得到该中国家庭SMBA家系人员AR基因的CAG复制数目,我们采用了PCR片段测序和基因分型两种方法. 在该SMBA家系中有两个已发病的成年男性、未发病的年轻男性,及女性基因携带者. 两个已发病男性患者AR基因中CAG三核苷酸串重复数目分别是48和45. 以前的研究表明特定三核苷酸串重复数目的扩增可导致人类遗传性神经障碍疾病发病。我们的研究结果完全支持这一观点,SMBA中国家系的三核苷酸CAG拷贝数目检测结果表明,AR基因CAG扩增数目与SMBA发病相关. 关键词雄性激素受体; CAG多重三核苷酸重复; 肯尼迪病; 脊延髓肌萎缩症; X连锁     

Weak strand displacement activity enables human DNA polymerase beta to expand CAG/CTG triplet repeats at strand breaks

Using synthetic DNA constructs in vitro, we find that human DNA polymerase beta effectively catalyzes CAG/CTG triplet repeat expansions by slippage initiated at nicks or 1-base gaps within short (14 triplet) repeat tracts in DNA duplexes under physiological conditions. In the same constructs, Escherichia coli DNA polymerase I Klenow Fragment exo(-) is much less effective in expanding repeats, because its much stronger strand displacement activity inhibits slippage by enabling rapid extension through two downstream repeats into flanking non-repeat sequence. Polymerase beta expansions of CAG/CTG repeats, observed over a 32-min period at rates of approximately 1 triplet added per min, reveal significant effects of break type (nick versus gap), strand composition (CTG versus CAG), and dNTP substrate concentration, on repeat expansions at strand breaks. At physiological substrate concentrations (1-10 microm of each dNTP), polymerase beta expands triplet repeats with the help of weak strand displacement limited to the two downstream triplet repeats in our constructs. Such weak strand displacement activity in DNA repair at strand breaks may enable short tracts of repeats to be converted into longer, increasingly mutable ones associated with neurological diseases.     

A genome-derived (gaa.ttc)24 trinucleotide block binds nuclear protein(s) specifically and forms triple helices

The properties of simple trinucleotide repeats generate increased interest as expansions of certain trinucleotide blocks cause human diseases. Here, we studied protein binding and structural features of a perfect (gaa.ttc)₂₄ tract in its original genomic environment. Electrophoretic mobility shift assays revealed that HeLa nuclear proteins bind to the DNA fragment containing the (gaa.ttc)₂₄ block. Competition experiments using simple (gt.ac)_n repeats differing in length and flanking regions showed no cross-reactivity with the major retarded band. For the specific (gaa.ttc)_n/protein complex, a binding constant of 9.3×10⁻⁹ mol/l was determined. DNase I footprinting revealed protein binding sites located exclusively within the repeat with a preference for the (gaa)₂₄ strand. OsO₄ and DEPC modifications followed by electrophoretic and electron microscopical analyses showed that the (gaa.ttc)₂₄ block forms different types of intramolecular triple helices: Under superhelical stress, different *H-DNA isomers are evident, whereas exclusively H-Y forms were detected in the relaxed state. Together, these data have functional implications for genomic (gaa.ttc)_n tracts.     

DNA base excision repair: a mechanism of trinucleotide repeat expansion

The expansion of trinucleotide repeat (TNR) sequences in human DNA is considered to be a key factor in the pathogenesis of more than 40 neurodegenerative diseases. TNR expansion occurs during DNA replication and also, as suggested by recent studies, during the repair of DNA lesions produced by oxidative stress. In particular, the oxidized guanine base 8-oxoguanine within sequences containing CAG repeats may induce formation of pro-expansion intermediates through strand slippage during DNA base excision repair (BER). In this article, we describe how oxidized DNA lesions are repaired by BER and discuss the importance of the coordinated activities of the key repair enzymes, such as DNA polymerase β, flap endonuclease 1 (FEN1) and DNA ligase, in preventing strand slippage and TNR expansion.     

Southern analysis for detection of CAG repeat expansions associated with dentatorubral pallidoluysian atrophy

Dentatorubral pallidoluysian atrophy (DRPLA) is an autosomal dominant neurodegenerative disorder caused by expansion of an unstable, tandemly repeated trinucleotide sequence, (CAG)_n, in a novel gene on human chromosome 12p12-pter. Molecular diagnosis of DRPLA uses the polymerase chain reaction (PCR) to amplify and characterize the number of CAG repeats carried by individuals. The PCR analysis is fairly straightforward when two alleles are identified. However, when only a single allele is observed, it is difficult to know whether the sample is homozygous or whether there was failure to amplify the second allele. We describe a Southern analysis for detection of the DRPLA CAG repeat, providing an independent method for the assessment of expanded alleles. Received: 15 May 1996 / Revised: 23 September 1996