Telomeric and dispersed repeat sequences in Candida yeasts and their use in strain identification.

Several different repetitive DNA sequences have been isolated from the pathogenic yeast Candida albicans. These include two families of large dispersed repeat sequences (Ca3, Ca24) and a short (23-bp) tandemly repeated element (Ca7) associated with C. albicans telomeres. In addition, a large subtelomeric repeat (WOL17) has been cloned. DNA fragments containing the telomeric repeats are highly variable among different C. albicans strains. We have shown that the Ca3 repeat is relatively more stable and is suitable for use as a species-specific and strain-specific probe for C. albicans.     

Telomeric sequences derived from laser-microdissected polytene chromosomes

Telomeric fragments from salivary gland squashes of Drosophila melanogaster Oregon R. were produced by a new microdissection technique, UV laser microbeam dissection. Microdissection, an essential step in microcloning procedures, is usually performed using micromanipulators and microneedles. Recently it has been shown that microdissection can be improved to very high precision if a laser coupled into a microscope is used. A laser microbeam, generated by an excimer pumped dye laser, allows chromosomes to be cut into slices of less than 0.5 m. Here it is shown, that single copy DNA probes prepared from Drosophila chromosomes by laser microdissection and microcloning relocalize to the chromosomal regions from which they are derived. The combination of laser technique and microcloning provides an advantageous approach for rapid genetic analysis with potential for the study of genetic diseases and genome mapping.     

Telomeric repeats act as nucleosome-disfavouring sequences in vivo

Telomeric DNAs consist of tandem repeats of G-clusters such as TTAGGG and TG_1-3, which are the human and yeast repeat sequences, respectively. In the yeast Saccharomyces cerevisiae, the telomeric repeats are non-nucleosomal, whereas in humans, they are organized in tightly packaged nucleosomes. However, previous in vitro studies revealed that the binding affinities of human and yeast telomeric repeat sequences to histone octamers in vitro were similar, which is apparently inconsistent with the differences in the human and yeast telomeric chromatin structures. To further investigate the relationship between telomeric sequences and chromatin structure, we examined the effect of telomeric repeats on the formation of positioned nucleosomes in vivo by indirect end-label mapping, primer extension mapping and nucleosome repeat analyses, using a defined minichromosome in yeast cells. We found that the human and yeast telomeric repeat sequences both disfavour nucleosome assembly and alter nucleosome positioning in the yeast minichromosome. We further demonstrated that the G-clusters in the telomeric repeats are required for the nucleosome-disfavouring properties. Thus, our results suggest that this inherent structural feature of the telomeric repeat sequences is involved in the functional dynamics of the telomeric chromatin structure.     

Telomeric repeat mutagenicity in human somatic cells is modulated by repeat orientation and G-quadruplex stability

Telomeres consisting of tandem guanine-rich repeats can form secondary DNA structures called G-quadruplexes that represent potential targets for DNA repair enzymes. While G-quadruplexes interfere with DNA synthesis in vitro, the impact of G-quadruplex formation on telomeric repeat replication in human cells is not clear. We investigated the mutagenicity of telomeric repeats as a function of G-quadruplex folding opportunity and thermal stability using a shuttle vector mutagenesis assay. Since single-stranded DNA during lagging strand replication increases the opportunity for G-quadruplex folding, we tested vectors with G-rich sequences on the lagging versus the leading strand. Contrary to our prediction, vectors containing human [TTAGGG]₁₀ repeats with a G-rich lagging strand were significantly less mutagenic than vectors with a G-rich leading strand, after replication in normal human cells. We show by UV melting experiments that G-quadruplexes from ciliates [TTGGGG]₄ and [TTTTGGGG]₄ are thermally more stable compared to human [TTAGGG]₄. Consistent with this, replication of vectors with ciliate [TTGGGG]₁₀ repeats yielded a 3-fold higher mutant rate compared to the human [TTAGGG]₁₀ vectors. Furthermore, we observed significantly more mutagenic events in the ciliate repeats compared to the human repeats. Our data demonstrate that increased G-quadruplex opportunity (repeat orientation) in human telomeric repeats decreased mutagenicity, while increased thermal stability of telomeric G-quadruplexes was associated with increased mutagenicity.     

Telomeric repeat organization--a comparative in situ study between man and rodent

Human, hamster, and mouse chromosomes show both similarities and differences in telomeric organization, detectable with a novel version of the PRINS technique. The differences allowed us to investigate the fate of the telomeres on a chromosome from one species when this chromosome was introduced into the cells of another species. For this purpose, we tested telomeres in cell lines of somatic cell hybrids containing human chromosomes on a rodent background, finding that the telomeres on human chromosomes could not be discriminated from the telomeres on rodent chromosomes. All telomeres in the cell lines were much shorter than the telomeres in normal cells. In the mouse-derived cell lines, half of the mouse chromosomes were fused to other mouse chromosomes at the ends of their short arms. At the points of fusion we were generally unable to detect telomeric signals. In these cell lines, we also found a fraction of chromosomes ends with only one telomeric signal. In chromosomes where both ends showed only one signal, the relative orientation of the signals appeared to be nonrandom with respect to sister chromatids.     

Telomeric repeat [TTAGGG]n sequences of human chromosomes are conserved in chimpanzee (Pan troglodytes)

Summary Using a series of genetic parameters, attempts have been made for more than two decades to establish the close kinship of human (Homo sapiens) with chimpanzee (Pan troglodytes). Molecular and cytogenetic data presently suggest that the two species are closely related. The recent isolation of a human telomeric probe (P5097-B.5) has prompted us to cross hybridize it to chimpanzee chromosomes in order to explore convergence and/or divergence of the telomeric repeat sequences (TTAGGG)_n. On hybridization, the human probe bound to both ends (telomeres) of chimpanzee chromosomes, suggesting a concerted evolution of tandemly repeated short simple sequences (TTAGGG)_n. Even the terminal heterochromatin of chimpanzee chromosomes was found to be endowed with telomeric repeats, suggesting that evolution of heterochromatin and capping with tandemly repeated short sequences are highly complex phenomena.     

Telomeric and interstitial telomeric-like DNA sequences in Orthoptera genomes.

A (TTAGG)n-specific telomeric DNA probe was hybridized to 11 orthopteroid insect genomes by fluorescence in situ hybridization. Nine different genera, mainly distributed within two evolutionary branches with male chromosome numbers 2n = 23 and 2n = 17 were included in the analysis. Telomere sequences yielded positive signals in every telomere and there was a considerable number of interstitial telomeric-like sequences, mainly located at the distal end of some, but not all, subterminal chromosome regions. One of the species, Pyrgomorpha conica, showed massive hybridization signals associated with constitutive heterochromatin. The results are discussed along two lines: (i) the chromosomal evolutionary trends within this group of insects and (ii) the putative role that ITs may play in a genome when they are considered telomere-derived, but not telomere-functional, DNA sequences.     

Ligase-based detection of mononucleotide repeat sequences

Up to 15% of all colorectal cancers are considered to be replication error positive (RER(+)) and contain mutations at hundreds of thousands of microsatellite repeat sequences. Recently, a number of intragenic mononucleotide repeat sequences have been demonstrated to be targets for inactivating genes in RER(+)colorectal tumors. In this study, thermostable DNA ligases were tested for the ability to detect alterations in microsatellite sequences in colon tumor samples. Ligation profiles on mononucleotide repeat sequences were determined for four related thermostable DNA ligases, Thermus thermophilus ( Tth ) ligase, Thermus sp. AK16D ligase, Aquifex aeolicus ligase and the K294R mutant of the Tth ligase. While the limit of detection for point mutations was one mutation in 1000 wild-type sequences, the ability to detect a single base deletion in a 10 base mononucleotide repeat was one mutation in 100 wild-type sequences. Furthermore, the misligation error increased exponentially as the length of the mono-nucleotide repeat increased, and was 10% of the correct signal for a 19 base mononucleotide repeat. A fluorescent ligase-based assay [polymerase chain reaction/ligase detection reaction (PCR/LDR)] correlated with results obtained using a radioactive assay to detect instability within the TGF-beta Type II receptor gene. PCR/LDR was also used to detect the APCI1307K mononucleotide repeat allele which has a carrier frequency of 6.1% in Ashkenazi Jewish individuals. In a blind study, 30 samples that had been typed for the presence of the APCI1307K allele were tested. The PCR/LDR results correlated with those obtained using sequencing and allele-specific oligonucleotide hybridization for 16 samples carrying the mutation and 13 wild-type samples. Ligation assays that characterize mononucleotide repeats can be used to rapidly detect somatic mutations in tumors, and to screen for individuals who have a hereditary predisposition to develop colon cancer.     

Inverted repeat sequences in the drosophila genome

The properties of inverted repeat (foldback) sequences in Drosophila melanogaster DNA have been studied by HAP chromatography and electron microscope methods. Electron microscope observations show that there is a broad distribution of lengths of the duplex regions of the inverted repeats from very short to greater than 15 kb, with number and weight average values of 1.35 kb and 5.0 kb respectively. About 20% of the inverted repeats are separated by a single-strand spacer with lengths too short to observe, but the other 80% have spacers, P, with lengths ranging from 0.5 kb to greater than 30 kb. The number average and weight average spacer lengths for the total sample are 2.7 kb and 6.1 kb. With respect to the lengths of the spacers, P, between inverted repeats, the Drosophila genome differs from that of most organisms which have been studied where the spacers P are mostly too short to be measured. EM and HAP studies suggest that the average center-to-center spacing between sets of inverted repeats is 40–80 kb. The HAP studies show that there is a broad range of thermal stabilities for the duplexes formed by reassociation of inverted repeat sequences. Kinetic analysis shows that all of the frequency components of the Drosophila genome are present in the inverted repeats, the loops P, and the flanking sequences. There is a somewhat larger proportion of middle repetitive DNA in those inverted repeat duplexes which are resistant to digestion by Mung Bean Endonuclease I. These enzyme resistant duplexes comprise about 3% of the entire genome. It is estimated that there are approximately 2000–4000 inverted repeat pairs in the entire genome.     

Vectorette PCR isolation of microsatellite repeat sequences using anchored dinucleotide repeat primers.

We have developed a vectorette PCR approach to provide an improved method for isolation of microsatellite repeats. The modified procedure relies on PCR amplification using a vectorette-specific primer in combination with one of a panel of anchored dinucleotide repeat primers. The target DNA to be screened for microsatellite sequences can be from YAC, P1, cosmid, bacteriophage or plasmid clones. We have used this technique to isolate novel, polymorphic microsatellite repeats from clones containing the amelogenin gene (AMGX) located on human chromosome Xp22.3.     

Transcription of complementary repeat sequences in amphibian oocytes

Repeat sequences are transcribed in the germinal vesicles of amphibian oocytes. In the hnRNA population both complements of the repeats are found and can be readily detected because they form intermolecular duplex structures. The structure and formation of duplex regions have been studied in the hnRNA of Xenopus laevis, Triturus cristatus, Amphiuma means and Necturus maculosus, a series of amphibians of increasing genome size (C-value). In T. cristatus, the duplex structures are mostly 600-1200 bp in length, whereas in X. laevis they are shorter and in N. maculosus they tend to be longer. Although the proportion of RNA sequence capable of rapidly forming duplex structures is different in different organisms, this property bears no relationship to C-value. However the sequence complexity of complementary repeats, as estimated from the rate of duplex formation, does show an increasing trend with C-value. The complementary repeats found in oocyte hnRNA are transcribed from families of DNA sequence that are each represented in the genome by thousands of copies. The extent of cross-species hybridization is low, indicating that the repeat sequences transcribed in different amphibian genera are not the same. In situ hybridization experiments indicate that the repeat sequences are spread throughout the genome. The evolution and possible function of complementary repeats are considered.     

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.     

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.     

Use of porcine interspersed repeat sequences in PCR-mediated genotyping

PCR primers derived from porcine short and long interspersed repeat sequences were used to amplify DNA samples isolated from individual members of threegeneration pig reference pedigrees. Subsequent high-resolution gel electrophoresis of both SINE and LINE-PCR products allowed direct visualisation of polymorphisms that segregated in a Mendelian manner. Additional polymorphisms were detected by Southern blotting of the gels described above followed by hybridization with simple sequence DNA. Genotyping by interspersed repeat-PCR exploits the natural architecture of the pig genome and allows the typing of polymorphisms by utilizing pre-existing sequence information.     

A clustering method for repeat analysis in DNA sequences

Background

A computational system for analysis of the repetitive structure of genomic sequences is described. The method uses suffix trees to organize and search the input sequences; this data structure has been used previously for efficient computation of exact and degenerate repeats.

Results

The resulting software tool collects all repeat classes and outputs summary statistics as well as a file containing multiple sequences (multi fasta), that can be used as the target of searches. Its use is demonstrated here on several complete microbial genomes, the entire Arabidopsis thaliana genome, and a large collection of rice bacterial artificial chromosome end sequences.

Conclusions

We propose a new clustering method for analysis of the repeat data captured in suffix trees. This method has been incorporated into a system that can find repeats in individual genome sequences or sets of sequences, and that can organize those repeats into classes. It quickly and accurately creates repeat databases from small and large genomes. The associated software (RepeatFinder), should prove helpful in the analysis of repeat structure for both complete and partial genome sequences.