A truncated acidic domain in Xenopus TRF1.

Telomere function is mediated by a complex of proteins bound to double-stranded and single-stranded telomeric repeats. A key player in this complex is TRF1, which binds to duplex TTAGGG repeats and acts as a negative regulator of telomere length. This protein's domain structure, as defined by studies with mammalian orthologs, consists of an N-terminal acidic domain, a dimerization domain, and a C-terminal Myb DNA binding domain. TRF1 from Xenopus laevis was cloned and sequenced, and the encoded protein found to have a similar structure but with a very short acidic domain. This short acidic domain was confirmed in Xenopus tropicalis, a true diploid, by cloning of cDNA sequences by RACE and analysis of the genomic locus. The TRF1 transcript is expressed in developing and adult frogs. Compared to the mammalian orthologs, the Xenopus genes are the most distantly related vertebrate examples characterized to date. Since adult Xenopus ubiquitously express somatic telomerase activity, proteins that regulate telomerase access to the chromosome ends are important in regulating telomere length in normal somatic tissue. The structure of Xenopus TRF1 has implications for its regulation by tankyrase.

Telomere variation in Xenopus laevis.

Eukaryotic telomeres are variable at several levels, from the length of the simple sequence telomeric repeat tract in different cell types to the presence or number of telomere-adjacent DNA sequence elements in different strains or individuals. We have investigated the sequence organization of Xenopus laevis telomeres by use of the vertebrate telomeric repeat (TTAGGG)n and blot hybridization analysis. The (TTAGGG)n-hybridizing fragments, which ranged from less than 10 to over 50 kb with frequently cutting enzymes, defined a pattern that was polymorphic between individuals. BAL 31 exonuclease treatment confirmed that these fragments were telomeric. The polymorphic fragments analyzed did not hybridize to 5S RNA sequences, which are telomeric according to in situ hybridization. When telomeric fragments from offspring (whole embryos) were compared to those from the spleens of the parents, the inheritance pattern of some bands was found to be unusual. Furthermore, in one cross, the telomeres of the embryo were shorter than the telomeres of the parents' spleen, and in another, the male's testis telomeres were shorter than those of the male's spleen. Our data are consistent with a model for chromosome behavior that involves a significant amount of DNA rearrangement at telomeres and suggest that length regulation of Xenopus telomeres is different from that observed for Mus spretus and human telomeres.

A novel minisatellite at a cloned hamster telomere.

The ends of eukaryotic chromosomes have special properties and roles in chromosome behavior. Selection for telomere function in yeast, using a Chinese hamster hybrid cell line as the source DNA, generated a stable yeast artificial chromosome clone containing 23 kb of DNA adjacent to (TTAGGG)n, the vertebrate telomeric repeat. The common repetitive element d(GT)n appeared to be responsible for most of the other stable clones. Circular derivatives of the TTAGGG-positive clone that could be propagated in E. coli were constructed. These derivatives identify a single pair of hamster telomeres by fluorescence in situ hybridization. The telomeric repeat tract consists of (TTAGGG)n repeats with minor variations, some of which can be cleaved with the restriction enzyme MnlI. Blot hybridization with genomic hamster DNA under stringent conditions confirms that the TTAGGG tracts are cleaved into small fragments due to the presence of this restriction enzyme site, in contrast to mouse telomeres. Additional blocks of (TTAGGG)n repeats are found approximately 4-5 kb internally on the clone. The terminal region of the clone is dominated by a novel A-T rich 78 bp tandemly repeating sequence; the repeat monomer can be subdivided into halves distinguished by more or less adherence to the consensus sequence. The sequence in genomic DNA has the same tandem organization in probably a single primary locus of >20-30 kb and is thus termed a minisatellite.

Tetrahymena micronuclear sequences that function as telomeres in yeast.

We explored the ability of S. cerevisiae to utilize heterologous DNA sequences as telomeres by cloning germline (micronuclear) DNA from Tetrahymena thermophila on a linear yeast plasmid that selects for telomere function. The only Tetrahymena sequences that functioned in this assay were (C4A2)n repeats. Moreover, these repeats did not have to be derived from Tetrahymena telomeres, although we show that micronuclear telomeres (like macronuclear telomeres) of Tetrahymena terminate in (C4A2)n repeats. Chromosome-internal restriction fragments carrying (C4A2)n repeats also stabilized linear plasmids and were elongated by yeast telomeric repeats. In one case, the C4A2 repeat tract was approximately 1.5 kb from the end of the genomic Tetrahymena DNA fragment that was cloned, but this 1.5 kb of DNA was missing from the linear plasmid. Thus, yeast can utilize internally located tracts of telomere-like sequences, after the distal DNA is removed. The data provide an example of broken chromo-some healing, and underscore the importance of the telomeric repeat structure for recognition of functional telomeric DNA in vivo.

Recognition and elongation of telomeres by telomerase.

Telomeres stabilize chromosomal ends and allow their complete replication in vivo. In diverse eukaryotes, the essential telomeric DNA sequence consists of variable numbers of tandem repeats of simple, G + C rich sequences, with a strong strand bias of G residues on the strand oriented 5' to 3' toward the chromosomal terminus. This strand forms a protruding 3' over-hang at the chromosomal terminus in three different eukaryotes analyzed. Analysis of yeast and protozoan telomeres showed that telomeres are dynamic structures in vivo, being acted on by shortening and lengthening activities. We previously identified and partially purified an enzymatic activity, telomere terminal transferase, or telomerase, from the ciliate Tetrahymena. Telomerase is a ribonucleoprotein enzyme with essential RNA and protein components. This activity adds repeats of the Tetrahymena telomeric sequence, TTGGGG, onto the 3' end of a single-stranded DNA primer consisting of a few repeats of the G-rich strand of known telomeric, and telomere-like, sequences. The shortest oligonucleotide active as a primer was the decamer G4T2G4. Structural analysis of synthetic DNA oligonucleotides that are active as primers showed that they all formed discrete intramolecular foldback structures at temperatures below 40 degrees C. Addition of TTGGGG repeats occurs one nucleotide at a time by de novo synthesis, which is not templated by the DNA primer. Up to 8000 nucleotides of G4T2 repeats were added to the primer in vitro. We discuss the implications of this finding for regulation of telomerase in vivo and a model for telomere elongation by telomerase.

Generation of telomere-length heterogeneity in Saccharomyces cerevisiae.

Chromosome ends in the lower eukaryotes terminate in variable numbers of tandem, simple DNA repeats. We tested predictions of a model in which these telomeric repeats provide a substrate for the addition of more repeats by a terminal transferase-like mechanism that, in concert with DNA polymerase and primase, effectively counterbalances the loss of DNA due to degradation or incomplete replication. For individual chromosome ends in yeast, the mean length of any given telomere was shown to vary between different clonal populations of the same strain and to be determined by the initial length of that telomere in the single cell giving rise to the clone. This type of variation was independent of the major yeast recombination pathway. The length heterogeneity at each telomeric end increased with additional rounds of cell division or DNA replication. Lengths of individual telomeres within a single clone varied independently of each other. Thus, this clonal variability is distinct from genetic regulation of chromosome length, which acts on all chromosome ends coordinately. These in vivo phenomena suggest that lengthening and shortening activities act on yeast telomeres during each round of replication.

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.

New temperature-sensitive mutants of Saccharomyces cerevisiae affecting DNA replication.

We have isolated new mutants of the yeast Saccharomyces cerevisiae that are defective in mitotic DNA synthesis. This was accomplished by directly screening 11000 newly isolated temperature-sensitive yeast clones for DNA synthesis defects. Ninety-seven different mutant strains were identified. Approximately half had the fast-stop DNA synthesis phenotype; synthesis ceased quickly after shifting an asynchronous population of cells to the restrictive temperature. The other half had an intermediate-rate phenotype; synthesis continued at a reduced rate for at least 3 h at the restrictive temperature. All of the DNA synthesis mutants continued protein synthesis at the restrictive temperature. Genetic complementation analysis of temperature-sensitive segregants of these strains defined 60 apparently new complementation groups. Thirty-five of these were associated with the fast-stop phenotype, 25 with the intermediate-rate phenotype. The fast-stop groups are likely to include many genes whose products play direct roles in mitotic S phase DNA synthesis. Some of the intermediate-rate groups may be associated with S phase as well. This mutant collection should be very useful in the identification and isolation of gene products necessary for yeast DNA synthesis, in the isolation of the genes themselves, and in further analysis of the DNA replication process in vivo.