A truncated human chromosome 16 associated with alpha thalassaemia is stabilized by addition of telomeric repeat (TTAGGG)n

The instability of chromosomes with breaks induced by X-irradiation led to the proposal that the natural ends of chromosomes are capped by a specialized structure, the telomere. Telomeres prevent end-to-end fusions and exonucleolytic degradation, enable the end of the linear DNA molecule to replicate, and function in cell division. Human telomeric DNA comprises approximately 2-20 kilobases (kb) of the tandemly repeated sequence (TTAGGG)n oriented 5'----3' in towards the end of the chromosome, interspersed with variant repeats in the proximal region. Immediately subtelomeric lie families of unrelated repeat motifs (telomere-associated sequences) whose function, if any, is unknown. In lower eukaryotes the formation and maintenance of telomeres may be mediated enzymatically (by telomerase) or by recombination; in man the mechanisms are poorly understood, although telomerase has been identified in HeLa cells. Here we describe an alpha thalassaemia mutation associated with terminal truncation of the short arm of chromosome 16 (within band 16p13-3) to a site 50 kb distal to the alpha globin genes, and show that (TTAGGG)n has been added directly to the site of the break. The mutation is stably inherited, proving that telomeric DNA alone is sufficient to stabilize the broken chromosome end. This mechanism may occur in any genetic disease associated with chromosome truncation.     

Recognition of a chromosome truncation site associated with alpha-thalassaemia by human telomerase

Telomeres define the ends of chromosomes; they consist of short tandemly repeated DNA sequences loosely conserved in eukaryotes (G1-8(T/A)1-4). Telomerase is a ribonucleoprotein which, in vitro, recognizes a single-stranded G-rich telomere primer and adds multiple telomeric repeats to its 3' end by using a template in the RNA moiety. In conjunction with other components, telomerase may balance the loss of telomeric repeats due to DNA replication. Another role of telomerase may be the de novo formation of telomeres. In eukaryotes like Tetrahymena, this process is an integral part of the formation of macronuclear chromosomes. In other eukaryotes this process stabilizes broken chromosomes. A case of human alpha-thalassaemia is caused by a truncation of chromosome 16 that has been healed by the addition of telomeric repeats (TTAGGG)n. Using an in vitro assay, I show here that human telomerase correctly recognizes the chromosome 16 breakpoint sequence and adds (TTAGGG)n repeats. The DNA sequence requirements are minimal and seem to define two modes of DNA recognition by telomerase.     

Spectroscopic investigation on the telomeric DNA base sequence repeat

Telomeres are protein-DNA complexes at the terminals of linear chromosomes, which protect chromosomal integrity and maintain cellular replicative capacity. From single-cell organisms to advanced animals and plants, structures and functions of telomeres are both very conservative. In cells of human and vertebral animals, telomeric DNA base sequences all are (TTAGGG)n. In the present work, we have obtained absorption and fluorescence spectra measured from seven synthesized oligonucleotides to simulate the telomeric DNA system and calculated their relative fluorescence quantum yields on which not only telomeric DNA characteristics are predicted but also possibly the shortened telomeric sequences during cell division are implied. Oligonucleotide 5′-TTAGGGTTAGGG holds a low relative fluorescence quantum yield and remarkable excitation energy innerconversion, which tallies with the telomeric sequence of (TTAGGG)n. This result shows that telomeric DNA has a strong non-radiative or innerconvertible capability.     

Circular dichroism spectroscopic studies on structures formed by telomeric DNA sequences in vitro

Telomere plays an important role in cellular processes, such as cell aging, death and carcinogenisis. Having special sequences, it can form quadruplex structure in vitro. Circular dichroism (CD) spectroscopic studies show that TTAGGG, (TTAGGG)2 and (TTAGGG)4 can all form quadruplex in vitro and exist mainly as parallel quadruplex without metal ions. Both K+ and Na+ can stabilize the tetrameric structure and facilitate the forming of anti-parallel conformation. Furthermore, the conformations of quadruplex can also be affected by sequence length, the nature and concentration of metal ions.     

Is there left-handed DNA at the ends of yeast chromosomes?

Tracts of the alternating copolymer poly(dGdT . dCdA) have been observed in a variety of eukaryotes. Such tracts are of particular interest since homopolymers of this sequence can exist in vitro as left-handed Z form DNA. We have found that the yeast Saccharomyces cerevisiae contains at least 30 poly(GT) tracts at dispersed genomic locations. We show here that one subset of these tracts is located at the ends (telomeres) of the yeast chromosome. In addition, we show that poly(dGdT . dCdA) tracts are added to the ends of the extrachromosomal ribosomal DNA molecules of Tetrahymena when cloned in yeast. These data represent the first reported association between a homopolymeric sequence and a chromosome structure.     

Telomeric repeat from T. thermophila cross hybridizes with human telomeres

The ends (telomeres) of eukaryotic chromosomes must have special features to ensure their stability and complete replication. Studies in yeast, protozoa, slime moulds and flagellates show that telomeres are tandem repeats of simple sequences that have a G-rich and a C-rich strand. Mammalian telomeres have yet to be isolated and characterized, although a DNA fragment within 20 kilobases of the telomeres of the short arms of the human sex chromosomes has been isolated. Recently we showed that a chromosome from the fission yeast Schizosaccharomyces pombe could, in some cases, replicate as an autonomous mini-chromosome in mouse cells. By extrapolation from other systems, we reasoned that mouse telomeres could be added to the S. pombe chromosome ends in the mouse cells. On setting out to test this hypothesis we found to our surprise that the telomeric probe used (containing both the S. pombe and Tetrahymena thermophila repeats) hybridized to a series of discrete fragments in normal mouse DNA and DNA from a wide range of eukaryotes. We show here that the sequences hybridizing to this probe are located at the telomeres of most, if not all, human chromosomes and are similar to the Tetrahymena telomeric-repeat component of the probe.     

Shotgun sequence assembly and recent segmental duplications within the human genome

Complex eukaryotic genomes are now being sequenced at an accelerated pace primarily using whole-genome shotgun (WGS) sequence assembly approaches. WGS assembly was initially criticized because of its perceived inability to resolve repeat structures within genomes. Here, we quantify the effect of WGS sequence assembly on large, highly similar repeats by comparison of the segmental duplication content of two different human genome assemblies. Our analysis shows that large (> 15 kilobases) and highly identical (> 97%) duplications are not adequately resolved by WGS assembly. This leads to significant reduction in genome length and the loss of genes embedded within duplications. Comparable analyses of mouse genome assemblies confirm that strict WGS sequence assembly will oversimplify our understanding of mammalian genome structure and evolution; a hybrid strategy using a targeted clone-by-clone approach to resolve duplications is proposed.     

Inhibition of telomerase by G-quartet DNA structures

The ends or telomeres of the linear chromosomes of eukaryotes are composed of tandem repeats of short DNA sequences, one strand being rich in guanine (G strand) and the complementary strand in cytosine. Telomere synthesis involves the addition of telomeric repeats to the G strand by telomere terminal transferase (telomerase). Telomeric G-strand DNAs from a variety of organisms adopt compact structures, the most stable of which is explained by the formation of G-quartets. Here we investigate the capacity of the different folded forms of telomeric DNA to serve as primers for the Oxytricha nova telomerase in vitro. Formation of the K(+)-stabilized G-quartet structure in a primer inhibits its use by telomerase. Furthermore, the octanucleotide T4G4, which does not fold, is a better primer than (T4G4)2, which can form a foldback structure. We conclude that telomerase does not require any folding of its DNA primer. Folding of telomeric DNA into G-quartet structures seems to influence the extent of telomere elongation in vitro and might therefore act as a negative regulator of elongation in vivo.     

Cloning of human telomeres by complementation in yeast

Telomeres confer stability on chromosomes by protecting them from degradation and recombination and by allowing complete replication of the end. They are genetically important as they define the ends of the linkage map. Telomeres of lower eukaryotes contain short repeats consisting of a G-rich and a C-rich strand, the G-rich strand running 5'-3' towards the telomere and extending at the end. Telomeres of human chromosomes share characteristics with those of lower eukaryotes including sequence similarity as detected by cross-hybridization. Telomeric repeats from many organisms can provide telomere function in yeast. Here we describe a modified yeast artificial chromosome (YAC) vector with only one telomere which we used to clone human telomeres by complementation in yeast. YACs containing human telomeres were identified by hydridization to an oligonucleotide of the trypanosome telomeric repeat. A subcloned human fragment from one such YAC is immediately subtelomeric on at least one human chromosome.     

贵州2种负蝗核型和C—带的比较研究

研究了短额负蝗AtractomorphasinensisI .Bol.和云南负蝗AtractomorphayunnanensisBietXia的核型和C—带。结果表明 :2种负蝗的染色体数目均为 2n(♂ ) =18+XO =19,全部为端部着丝粒染色体 :核型公式 2n(♂ ) =2X =19t ,NF =19,都属“4B”核型 ,按相对长度 ,它们的染色体都可分成L ,M 2组 ,都具有着丝粒C带。云南负蝗后期Ⅰ染色体组绝对长度总和 (4 9 91± 0 37μm)比短额负蝗的 (4 2 5 0± 0 34 μm)长 ;但结构异染色质总量 (2 8 38± 0 2 2 % )却比短额负蝗的 (38 96± 0 16 % )少。     

Molecular cloning of human telomeres in yeast

Telomeres are the DNA sequences found at the ends of linear chromosomes. They define the boundaries of the genetical and physical maps of such chromosomes and so are particularly important for the complete mapping of large genomes that is now being attempted. Telomeres have been intensively studied in the yeast Saccharomyces cerevisiae and in ciliated protozoa: in these organisms the telomeric DNA consists of arrays of tandemly repeated short sequences in which one strand is guanosine-rich and oriented 5' to 3' towards the chromosome end. The conservation of these structural features is reflected in the observation that telomeric DNA from a variety of protozoa will function as telomeres on artificial linear mini-chromosomes in yeast. Tandem arrays of the sequence TTAGGG have been identified at the telomeres of humans and other mammals and also of trypanosomes. This indicates that the structural features of telomeres are conserved between higher and lower eukaryotes and implies that human telomeric DNA could function in yeast. I have used this idea to develop a strategy to isolate a specific human telomere as a molecular clone in yeast and have devised a simple and effective way of cloning other human telomeres and their associated sequences.     

Structural details of an adenine tract that does not cause DNA to bend

Runs of adenines (adenine tracts) have been implicated as the main determinant of sequence-directed DNA bending. The most widely used experimental test for bending relies on the observation that bent DNA migrates more slowly than straight DNA on a polyacrylamide electrophoresis gel. It was shown recently that the polymer (GTTTTAAAAC)n runs with normal mobility on a gel, whereas (GAAAATTTTC)n runs more slowly and thus appears to be strongly bent. The observation that these similar sequences, which differ only in the order of the adenine and thymine tracts, adopt such different shapes offers a stringent test of theories to explain DNA bending. Although the wedge model for DNA bending has recently been elaborated to explain the gel mobilities of these molecules, we wished to determine experimentally the structural basis for the difference in bending. We report here measurements of the frequency of cleavage by the hydroxyl radical at each nucleotide of cloned versions of the two polymers (see Fig. 1). We show that the TTTTAAAA sequence does not display the cleavage pattern that is associated with bent DNA, whereas the AAAATTTT sequence does. The observed sequence dependence of the cleavage pattern of an adenine tract is at odds with current models for DNA bending, which assume that adenine tracts always adopt the same conformation.     

Circular dichroism spectroscopic studies on structures formed by telomeric DNA sequencesin vitro

Telomere plays an important role in cellular processes, such as cell aging, death and carcinogenisis. Having special sequences, it can form quadruplex structurein vitro. Circular dichroism (CD) spectroscopic studies show that TTAGGG, (TTAGGG)₂ and (TTAGGG)₄ can all form quadruplexin vitro and exist mainly as parallel quadruplex without metal ions. Both K⁺ and Na⁺ can stabilize the tetrameric structure and facilitate the forming of anti-parallel conformation. Furthermore, the conformations of quadruplex can also be affected by sequence length, the nature and concentration of metal ions.     

Modulation of virulence within a pathogenicity island in vancomycin-resistant Enterococcus faecalis

Enterococci are members of the healthy human intestinal flora, but are also leading causes of highly antibiotic-resistant, hospital-acquired infection. We examined the genomes of a strain of Enterococcus faecalis that caused an infectious outbreak in a hospital ward in the mid-1980s (ref. 2), and a strain that was identified as the first vancomycin-resistant isolate in the United States, and found that virulence determinants were clustered on a large pathogenicity island, a genetic element previously unknown in this genus. The pathogenicity island, which varies only subtly between strains, is approximately 150 kilobases in size, has a lower G + C content than the rest of the genome, and is flanked by terminal repeats. Here we show that subtle variations within the structure of the pathogenicity island enable strains harbouring the element to modulate virulence, and that these variations occur at high frequency. Moreover, the enterococcal pathogenicity island, in addition to coding for most known auxiliary traits that enhance virulence of the organism, includes a number of additional, previously unstudied genes that are rare in non-infection-derived isolates, identifying a class of new targets associated with disease which are not essential for the commensal behaviour of the organism.     

DNA sequences of telomeres maintained in yeast

Telomeres, the ends of eukaryotic chromosomes, have long been recognized as specialized structures. Their stability compared with broken ends of chromosomes suggested that they have properties which protect them from fusion, degradation or recombination. Furthermore, a linear DNA molecule such as that of a eukaryotic chromosome must have a structure at its ends which allows its complete replication, as no known DNA polymerase can initiate synthesis without a primer. At the ends of the relatively short, multi-copy linear DNA molecules found naturally in the nuclei of several lower eukaryotes, there are simple tandemly repeated sequences with, in the cases analysed, a specific array of single-strand breaks, on both DNA strands, in the distal portion of the block of repeats. In general, however, direct analysis of chromosomal termini presents problems because of their very low abundance in nuclei. To circumvent this problem, we have previously cloned a chromosomal telomere of the yeast Saccharomyces cerevisiae on a linear DNA vector molecule. Here we show that yeast chromosomal telomeres terminate in a DNA sequence consisting of tandem irregular repeats of the general form C1-3A. The same repeat units are added to the ends of Tetrahymena telomeres, in an apparently non-template-directed manner, during their replication on linear plasmids in yeast. Such DNA addition may have a fundamental role in telomere replication.     

Similar level of polyteny in bands and interbands of Drosophila giant chromosomes

The giant polytene chromosomes of Drosophila melanogaster have long been of interest to the geneticist because of the visible map of the genome provided by their characteristic banding patterns. An issue in the understanding of the molecular basis of chromosome banding has been whether the chromosomal DNA is replicated to the same extent in bands and interbands. Although various suggestions have been put forward the point has remained controversial. We have isolated 315 kilobases (kb) of contiguous Drosophila genomic DNA which spans an interval of approximately 13 bands and interbands of the polytene chromosomes. We report here the measurement of the relative level of DNA replication in polytene chromosomes of 84 adjacent restriction fragments of our cloned DNA. We conclude that there are no significant differences in the level of polyteny within the large band and between bands and interbands of this region. This result supports the 'folded fibre' model of polytene chromosome organization, rather than models involving disproportionate replication along the banding pattern.     

Construction of artificial chromosomes in yeast

Fifty-five-kilobase long artificial chromosomes containing cloned genes, replicators, centromeres and telomeres have been constructed in yeast. These molecules have many of the properties of natural yeast chromosomes. Centromere function is impaired on short (less than 20 kilobases) artificial chromosomes.     

Covalently closed circles of adenovirus 5 DNA

The genome of adenoviruses is a double-stranded linear DNA molecule with inverted terminal repeats about 100 base pairs (bp) in length and a terminal protein covalently linked to the 5' nucleotide of each strand. Both of these features permit the formation of DNA circles, the inverted repeats allowing the circularization of single-stranded DNA and the terminal protein the joining of one or more molecules to yield double-stranded circles or concatemers. However, although the existence of covalently closed circles has been postulated, double-stranded viral DNA purified from virions or infected cells by conventional methods (that is, using proteases and phenol or chloroform) has always been obtained in a linear form. Here, we present evidence for the existence in adenovirus 5 (Ad5) infected cells of novel structures resulting from covalent head-to-tail joining of viral DNA molecules and show that these structures are due at least in part to the formation of covalently closed circles.