A molecular description of telometic heterochromatin in secale species

Rapid changes in amplification and methylation pattern of genomic DNA in cultured carrot root explants (Daucus carota L.)

Rapid genomic DNA variation due to methylation and copy number alteration was observed in carrot root explants 6 h after inoculation and during a 36-h period of exponential callus growth. De novo methylation and amplification of restricted BspNI fragments of low molecular weight occurred before cell cycle activation and should, therefore, be independent of progression through the S-phase of the cell cycle. Growth regulators seemed to influence the amplification pattern indirectly by regulating cell division activity. In exponentially growing callus tissue the copy number of most of the repetitive fragments was dramatically reduced. It is presumed that this reduction in the copy number of repetitive fragments is characteristic of 'rejuvenilization'. 3-Indole-acetic-acid (IAA) and inositol in the medium increased the degree of unspecific genomic DNA methylation in growing rhizogenic carrot callus tissue in the absence of kinetin, which inhibits root induction at that stage. A possible relation to the induction of rhizogenesis is considered. The observed reduction in number of repetitive restriction fragments and the increase in DNA methylation are gross changes covering the total genome. The results are discussed in relation to the controversy concerning the general biological significance of the methylation and amplification of DNA sequences.

Structure and evolution of a highly repetitive DNA sequence from Brassica napus

A Hind III family of highly repetitive DNA sequences, canrep (canola repeat), was cloned from the nuclear DNA of canola (Brassica napus cv. Westar). The basic units of this family of repeats consists of 176 bp and are arranged in clusters of tandem direct repeats. Each canrep repeat is composed of three related subrepeats of ca. 60 bp. Each subrepeat contains two inverted repeats of about 23 bp and another unrelated sequence of about 12 bp. Based on the internal structure, a possible scheme for the evolution of canrep is proposed. At least two subfamilies of the canrep sequences are present in the genome, as revealed by sequence analyses. In situ hybridization showed that canrep sequences are mainly clustered at centromeric regions of chromosomes. Northern hybridizations indicate that there are no transcripts related to canrep in the total RNAs extracted from plant seedlings.

Characterization of differences between whiteflies using RAPD-PCR

The B biotype of the sweetpotato whitefly, Bemisia tabaci (Gennadius) has caused over $200 million in crop damage in the US during 1992. The taxonomic classification of the A and B biotypes of B. tabaci is unclear. We used RAPD-PCR to demonstrate DNA differences between the A and B biotypes of this insect. All twenty of the RAPD primers tested distinguished readily between the biotypes. DNA extracted from individual eggs and nymphs showed identical differences. RAPD-based genetic similarity statistics indicate that these two biotypes of B. tabaci were no more similar to each other than to two other whitefly species: bayberry whitefly (Parabemisia myricae) or bandedwinged whitefly (Trialeurodes abutilonea). These results indicate that RAPD-PCR may be useful in distinguishing closely related organisms, but may not be useful in determining higher classification of insects. Before the taxonomic status of B. tabaci biotypes A and B can be determined, results from other genetic, morphological and physiological examinations will have to be compared.

Chromosome location of Oryza sativa recombination linkage groups

In situ hybridization, a powerful tool for the molecular cytogeneticist, can be used to physically map repetitive, low-copy, and unique DNA sequences in plant chromosomes. With the availability of a recombination map in Oryza sativa L. and an improved in situ hybridization technique, this study was designed to establish the relationship between the genetic and physical distances of the rice restriction fragment length polymorphism map. Analysis indicated that considerable variation can exist between genetic and physical maps. A 183-centimorgan linkage map for chromosome 2 covered less than 50% of the chromosome and did not include the centromere, whereas a 91-centimorgan linkage map for chromosome 1 covered approximately 80% of the chromosome. The results indicated that there are potential "hot" and "cold" spots of recombination and polymorphisms in rice, which involve both genes and restriction fragment length polymorphisms.

Characterization of Arabidopsis thaliana telomeres isolated in yeast

In an effort to learn more about the genomic organization of chromosomal termini in plants we employed a functional complementation strategy to isolate Arabidopsis thaliana telomeres in the yeast, Saccharomyces cerevisiae. Eight yeast episomes carrying A. thaliana telomeric sequences were obtained. The plant sequences carried on two episomes, YpAtT1 and YpAtT7, were characterized in detail. The telomeric origins of YpAtT1 and YpAtT7 insert DNAs were confirmed by demonstrating that corresponding genomic sequences are preferentially degraded during exonucleolytic digestion. The isolated telomeric restriction fragments contain G-rich repeat arrays characteristic of A. thaliana telomeres, as well as subterminal telomere-associated sequences (TASs). DNA sequence analysis revealed the presence of variant telomeric repeats at the centromere-proximal border of the terminal block of telomere repeats. The TAS flanking the telomeric G-rich repeat in YpAtT7 corresponds to a repetitive element present at other A. thaliana telomeres, while more proximal sequences are unique to one telomere. The YpAtT1 TAS is unique in the Landsberg strain of A. thaliana from which the clone originated; however, the Landsberg TAS cross-hybridizes weakly to a second telomere in the strain Columbia. Restriction analysis with cytosine methylation-sensitive endonucleases indicated that both TASs are highly methylated in the genome.

A novel repetitive DNA sequence in the genus Oryza

Repetitive DNA sequences in the genus Oryza (rice) represent a large fraction of the nuclear DNA. The isolation and characterization of major repetitive DNA sequences will lead to a better understanding of rice genome organization and evolution. Here we report the characterization of a novel repetitive sequence, CC-1, from the CC genome. This repetitive sequence is present as long tandem arrays with a repeat unit 194 bp in length in the CC-diploid genome but 172 bp in length in the BBCC and CCDD tetraploid genomes. This repetitive sequence is also present, though at lower copy numbers, in the AA and BB genomes, but is absent in the EE and FF genomes. Hybridization experiments revealed considerable differences both in copy numbers and in restriction fragment patterns of CC-1 both between and within rice species. The results support the hypothesis that the CC genome is more closely related to the AA genome than to the BB genome, and most distantly related to the EE and FF genomes.

Molecular and cytogenetic characterization of repetitive DNA sequences from Lolium and Festuca: applications in the analysis of Festulolium hybrids

A set of species-specific repetitive DNA sequences was isolated from Lolium multiflorum and Festuca arundinacea. The degree of their species specificity as well as possible homologies among them were determined by dot-blot hybridization analysis. In order to understand the genomic organization of representative Lolium and Festuca-specific repetitive DNA sequences, we performed Southern blot hybridization and in situ hybridization to metaphase chromosomes.Southern blot hybridization analysis of eight different repetitive DNA sequences of L. multiflorum and one of F. arundinacea indicated either tandem and clustered arrangements of partially dispersed localization in their respective genomes. Some of these sequences, e.g. LMB3, showed a similar genomic organization in F. arundinacea and F. pratensis, but a slightly different organization and degree of redundancy in L. multiflorum. Clones sequences varied in size between 100 bp and 1.2 kb. Estimated copy number in the corresponding haploid genomes varied between 300 and 2×10(4). Sequence analysis of the highly species-specific sequences from plasmids pLMH2 and pLMB4 (L. multiflorum specific) and from pFAH1 (F. arundinacea specific) revealed some internal repeats without higher order. No homologies between the sequences or to other repetitive sequences were observed. In situ hybridization with these latter sequences to metaphase chromosomes from L. multiflorum, F. arundinacea and from symmetric sexual Festulolium hybrid revealed their relatively even distribution in the corresponding genomes. The in situ hybridization thus also allowed a clearcut simple identification of parental chromosomes in the Festulolium hybrid.The potential use of these species-specific clones as hybridization probes in quantitative dot-blot analysis of the genomic make-up of Festulolium (sexual and somatic) hybrids is also demonstrated.

Organization of repeated sequences in species of the genus Avena

Four repetitive sequences from Avena murphyi have been isolated and their genome organization studied in different species of the genus Avena. A tandem sequence array was found for the Avena species that contain the C genome. Three other dispersed sequences present in the A and C genomes were arranged in a genomespecific manner. The fact that no major differences in the hybridization patterns were found between species with the same basic genome is consistent with the current taxonomy of Avena species.

Heat-shock induction and cytoplasmic localization of transcripts from telomeric-associated sequences in Chironomus thummi

Transcription of telomeric-associated sequences has been detected in the salivary gland cells of the larvae Chironomus thummi. In this species, a heat shock induces puffing at some telomeres, especially at one of the telomeres of chromosome III. We found that this process was concomitant with an increase in the overall telomeric transcript levels. Transcription was also observed in all the telomeres under control conditions, by in situ hybridization, even when these telomeres appeared to be in a nonpuffed state. The telomeric transcripts were found in both, the nuclei and, at higher levels, in the cytoplasmic extracts of salivary gland cells. The heat-shock activation, however, appeared to be restricted to the nuclear level. Telomeric transcription and the peculiar behavior of C. thummi telomeres after a heat shock are discussed.

Distribution and evolution of two satellite DNAs in the genus Beta

EcoRI monomers of a highly repetitive DNA family of Beta vulgaris have been cloned. Sequence analysis revealed that the repeat length varies between 157-160 bp. The percentage of AT-residues is 62% on average. The basic repeat does not show significant homology to the BamHI sequence family of B. vulgaris that was analyzed by us earlier. Both the EcoRI and BamHI sequences are investigated and compared to each other with respect to their genomic organization in the genus Beta. Both repeats were found to be tandemly arranged in the genome of B. vulgaris in a satellite-like manner. The EcoRI satellite DNA is present in three sections (Beta, Corollinae and Nanae) of the genus, whereas the BamHI satellite DNA exists only in the section Beta. The distribution of the EcoRI and BamHI satellite families in the genus is discussed with respect to their evolution.

The cytogenetic and molecular architecture of chromosome 1R--one of the most widely utilized sources of alien chromatin in wheat varieties

Chromosome 1R of rye (Secale cereale) is one of the most intensively used sources of alien chromatin in bread wheat. It provides a source of valuable disease resistance genes and its widespread use has stimulated the development of genetic maps incorporating protein and DNA markers. Published data as well as new mapping data were combined into a consensus map by using common markers in the different mapping studies to orient the various data sets relative to each other. The consensus map provides a tentative order, and relative distances, between the genetic markers. A summary of the dispersed repetitive sequences that are now available for the detection and characterization of chromosome 1R segments in wheat is also provided.

Localization of specific repetitive DNA sequences in individual rice chromosomes

This paper describes the characterization and chromosomal distribution of three different rice (Oryza sativa) repetitive DNA sequences. The three sequences were characterized by sequence analysis, which gave 355, 498 and 756 bp for the length of the repeat unit in Os48, OsG3-498 and OsG5-756, respectively. Copy number determination by quantitative DNA slot-blot hybridization analysis showed 4000, 1080 and 920 copies, respectively, per haploid rice genome for the three sequences. In situ DNA hybridization analysis revealed that 95% of the silver grains detected with the Os48 probe were localized to euchromatic ends of seven long arms and one short arm out of the 12 rice chromosomes. For the OsG3-498 repetitive sequence, the majority of silver grains (58%) were also clustered at the same chromosomal ends as that of Os48. The minority (28%) of silver grains were located at heterochromatic short arms and centromeric regions. For the OsG5-756 repetitive sequence, 81% of the silver grains labeled the heterochromatic short arms and regions flanking all of the 12 centromeres. Thus, each of these three repetitive sequences was distributed at specific defined chromosomal locations rather than randomly at many chromosomal locations. The approximate copy number of a given repetitive DNA sequence at any specific chromosomal location was calculated by combining the information from in situ DNA hybridization analysis and the total copy number as determined by DNA slot-blot hybridization.

Repeated DNA in Pneumocystis carinii

A 16-kb DNA fragment designated Rp3-1 and cloned from the genome of rat-derived Pneumocystis carinii was found to contain sequences that were repeated approximately 70 times per genome. The repeated sequences in Rp3-1 spanned at least 10.4 kb. Sequences in Rp3-1 were present on each of the 16 P. carinii chromosomes resolved by field inversion gel electrophoresis. Most of the P. carinii genomic sequences homologous to those in the Rp3-1 clone appeared to be as long as those in the Rp3-1 clone but were highly polymorphic with respect to restriction enzyme cleavage sites. The Rp3-1 DNA fragment appears to be a member of a family of large, degenerate, dispersed repeats.

In situ hybridization as a rapid means to assess meiotic pairing and detection of alien DNA transfers in interphase cells of wide crosses involving wheat and rye

The objectives of this study were to determine if biotin-labelled total genomic DNA of rye (Secale cereale L.) could be used to (i) preferentially label rye meiotic chromosomes in triticale and (ii) detect translocation stocks at interphase and/or early prophase by in situ hybridization. Welsh triticale, a wheat-rye segmental amphiploid, and Kavkaz wheat, a wheat-rye translocation were used. The results indicated that labelled chromosomes of rye and unlabelled chromosomes of wheat could be observed throughout all meiotic stages in the triticale. For Kavkaz wheat, the presence of the translocated 1RS chromosome arm of rye was detected at the interphase or very early prophase stage. Rapid assessment of feasibility of gene transfers and detection of alien DNA in somatic cells at the interphase stage by in situ hybridization allows for rapid decision-making and saves time and expense in plant breeding programs.

A genome-specific repeat sequence from kiwifruit (Actinidia deliciosa var. deliciosa)

Six members of a family of moderately repetitive DNA sequences from kiwifruit (Actinidia deliciosa var. deliciosa) have been cloned and characterized. The repeat family is composed of elements that have a unit length of 463 bp, are highly methylated, occur in tandem arrays of at least 50 kb in length, and constitute about 0.5% of the kiwifruit genome. Individual elements diverge in nucleotide sequence by up to 5%, which suggests that the repeat sequence is evolving rapidly. Homologous sequences were found in A. deliciosa var. chlorocarpa. The repeat sequence was not found under low stringency hybridization conditions in the diploid A. chinensis, the species most closely related to the hexaploid kiwifruit, or in eight other Actinidia species. However, homologous repeats were detected in a tetraploid species, A. chrysantha. The results provide the first molecular evidence to suggest that kiwifruit may be an allopolyploid species.

Subrepeats result from regional DNA sequence conservation in tandem repeats in Chironomus telomeres

Repeat units, widespread in eukaryotic genomes, are often partially or entirely built up of subrepeats. Homogenization between whole repeat units arranged in tandem usually can best be understood as a result of unequal crossing over. Such a mechanism is less plausible for maintaining similarities between subrepeats within a repeat unit when present in a regular array. In Chironomus telomeres, large blocks of tandemly repeated approximately 350 base-pair units contain two or three pairs of subrepeats with high mutual identities, embedded in linker DNA, non-repetitive within the repeat unit. Measurements of evolutionary base changes in two closely related species, Chironomus tentans and Chironomus pallidivittatus, permit us to conclude that the subrepeat arrangement is best explained as a consequence of regional sequence conservation after an earlier duplication of an ancestral half-unit.

Structure and polymorphism of human telomere-associated DNA

We have analyzed the DNA sequences associated with four different human telomeres. Two are members of distinct repeated sequence families which are located mainly but not exclusively at telomeres. Two are unique in the genome, one deriving from the long arm telomere of chromosome 7 and the other from the pseudoautosomal telomere. One telomere-associated repeated sequence has a polymorphic distribution among the chromosome ends, being present at a different combination of ends in different individuals. These data thus identify a new source of human genetic variation and indicate that the canonical features of the organization of telomere-associated DNA are widely conserved in evolution.

Characterization of relic DNA from barley genome

High-molecular-weight "relic" DNA fraction can be electrophoretically separated from the bulk of barley DNA digested with different restriction enzymes. We have cloned and analyzed a population of relic DNA fragments. The majority of AluI-relic DNA clones contained barley simple sequence satellite DNA and other families of repetitive DNA. One of these families, designated HvRT, has been analyzed in detail. This family is composed of tandemly arranged 118-bp monomers and is present in 7 × 10(5) copies in the barley genome. Clones representing the HvRT family were sequenced. HvRT repeats were found to contain high levels of methylated cytosine. The HvRT family was found in the genomes of H. vulgare, H. leporinum, H. murinum, H. jubatum, but not in H. marinum, H. geniculatum, and wheat. Different barley species and cultivars show restriction fragment length polymorphism with the HvRT probe. Chromosome-specific subfamilies of HvRT were found to be present on different barley chromosomes, providing the possibility of using the HvRT probe as a chromosome specific marker. HvRT fragments up to 810 kbp in length were resolved by pulsed field gel electrophoresis.

Hordeum chilense repetitive sequences. Genome characterization using biotinylated probes

A library of random DNA fragment clones of wild barley Hordeum chilense was screened for clones of repeated nucleotide sequences. Five clones were isolated that gave a stronger hybridization signal in colony and dot blot hybridization with total H. chilense DNA in comparison to Triticum aestivum DNA. Clones labelled with biotinylated nucleotides were used as probes to investigate the repeated sequences organization in the H. chilense genome. Tandemly arranged and interspersed sequences have been found, together with homology differences with related sequences present in T. Aestivum, which could allow the differentiation of H. chilense DNA when it is present in wheat. We show that biotin can replace the use of (32)P in preparing repeated sequence probes for Southern and DNA dot blot analyses.

Discrimination between closely related Triticeae species using genomic DNA as a probe

Labelled total genomic DNA was used as a probe in combination with blocking DNA to discriminate between taxonomically closely related species in the genera Hordeum and Secale. Discrimination was possible both by Southern hybridization to size-fractionated restriction enzyme digests of genomic DNA and by in situ hybridization to chromosome preparations. To distinguish between two species (e.g. H. vulgare and H. bulbosum), genomic DNA from one species was used as the labelled probe, while unlabelled DNA from the other species was applied at a much higher concentration as a block. The blocking DNA presumably hybridized to sequences in common between the block and the labelled probe, and between the block and DNA sequences on the membrane or chromosomes in situ. If so, mainly species-specific sequences would remain as sites for probe hybridization. These species-specific sequences are dispersed and represent a substantial proportion of the genome (unlike many cloned, species-specific sequences). Consequently, rapid nonradioactive methods detected probe hybridization sites satisfactorily. The method was able to confirm the parentage of hybrid plants. It has potentially wide application in plant breeding for the detection of alien DNA transfer, and it can be easily adapted to many species.

Physical mapping of a low-copy DNA sequence in rye (Secale cereale L.)

A 900-base-pair (bp) sequence from a cDNA clone of the rye endosperm-storage-protein gene Sec-1 was labeled with biotin and hybridized to Secale cereale 'Blanco' chromosomes. Hybridization was seen on the satellite part of the short arm of chromosome 1R, where the Sec-1 gene has been genetically mapped, in approximately 8.5% of the cells analyzed. The clone cross-hybridized at a lower frequency to rye chromosome arms 1R (long) (4.4%) and 2R (short) (2.6%), where two additional rye storage-protein loci, Sec-3 and Sec-2, respectively, have been mapped. A fourth hybridization site was observed on the short arm of chromosome 6R at a frequency of 3.0%. The cross-hybridization is attributed to a combination of residual sequence homology between the protein loci and the low-stringency conditions used in in situ hybridization. In situ hybridization mapping, in combination with chromosome walking by using molecular techniques, is suggested as an excellent approach to physical mapping of chromosomes.

Construction of Beta procumbens-specific DNA probes and their application for the screening of B. vulgaris x B. procumbens (2n = 19) addition lines

Beta procumbens-specific DNA probes have been constructed by cloning digested total DNA in E. coli and screening the resulting recombinant plasmids in dot blot hybridizations with labelled B. procumbens and B. vulgaris DNA. Four clones (pTS1-4) have been analyzed in detail determining their degree of specificity and DNA sequence. Two clones (pTS1 and pTS2) with the highest degree of B. procumbens specificity were adapted for the squash dot hybridization with the aim of screening large numbers of individual hybrid plants (B. vulgaris x B. procumbens) carrying an alien B. procumbens chromosome (2n = 19). These addition lines carry in some cases B. procumbens resistance genes to the beet cyst nematode (Heterodea schachtii Schm.).

Dialect-I, species-specific repeated DNA sequence from barley, Hordeum vulgare

Dialect-1, species-specific repetitive DNA sequence of barley Hordeum vulgare, was cloned and analysed by Southern blot and in situ hybridization. Dialect-1 is dispersed through all barley chromosomes with copy number 5,000 per genome. Two DNA fragments related to Dialect-1 were revealed in λ phage library, subcloned and mapped. All three clones are structurally heterogenous and it is suggested that the full-length genomic repeat encompassing Dialect-1 is large in size. The Dialect-1 DNA repeat is represented in the genomes of H. vulgare and ssp. agriocrithon and spontaneum in similar form and copy number; it is present in rearranged form with reduced copy number in the genomes of H. bulbosum and H. murinum, and it is absent from genomes of several wild barley species as well as from genomes of wheat, rye, oats and maize. Dialect-1 repeat may be used as a molecular marker in taxonomic studies and for identification of barley chromosomes in interspecies hybrids.

Isolation and characterization of a human telomere

A method is described that allows cloning of human telomeres in S. cerevisiae by joining human telomeric restriction fragments to yeast artificial chromosome halves. The resulting chimeric yeast-human chromosomes propagate as true linear chromosomes, demonstrating that the human telomere structure is capable of functioning in yeast and suggesting that telomere functions are evolutionarily conserved between yeast and human. One cloned human telomere, yHT1, contains 4 kb of human genomic DNA sequence next to the tandemly repeating TTAGGG hexanucleotide. Genomic hybridizations using both cloned DNA and TTAGGG repeats have revealed a common structural organization of human telomeres. This 4 kb of genomic DNA sequence is present in most, but not all, human telomeres, suggesting that the region is not involved in crucial chromosome-specific functions. However, the extent of common features among the human telomeres and possible similarities in organization with yeast telomeres suggest that this region may play a role in general chromosome behavior such as telomere-telomere interactions. Unlike the simple telomeric TTAGGG repeats, our cloned human genomic DNA sequence does not cross-hybridize with rodent DNA. Thus, this clone allows the identifications of the terminal restriction fragments of specific human chromosomes in human-rodent hybrid cells.

Genome-specific repetitive sequences in the genus Oryza

Repetitive DNA sequences are useful molecular markers for studying plant genome evolution and species divergence. In this paper, we report the isolation and characterization of four genome-type specific repetitive DNA sequences in the genus Oryza. Sequences specific to the AA, CC, EE or FF genome types are described. These genome-type specific repetitive sequences will be useful in classifying unknown species of wild or domestic rice, and in studying genome evolution at the molecular level. Using an AA genome-specific repetitive DNA sequence (pOs48) as a hybridization probe, considerable differences in its copy number were found among different varieties of Asian-cultivated rice (O. sativa) and other related species within the AA genome type. Thus, the relationship among some of the members of AA genome type can be deduced based on the degree of DNA sequence similarity of this repetitive sequence.

Cloning human telomeric DNA fragments into Saccharomyces cerevisiae using a yeast-artificial-chromosome vector

Telomeric fragments of human DNA ranging in size from 50 to 250 kilobases were cloned into Saccharomyces cerevisiae using a yeast-artificial-chromosome (YAC) vector. Six human-telomeric YAC (HTY) strains were selected by virtue of the specific hybridization of their DNA with the human telomeric terminal-repeat sequence (TTAGGG)n, and the telomeric localization of this sequence within each YAC was demonstrated by its sensitivity to nuclease BAL-31. In situ hybridization of DNA from three of these HTY strains with human metaphase chromosomes yielded discrete patterns of hybridization signals at the telomeres of a limited number of human chromosomes, different for each clone. DNA from selected cosmid subclones of one of the HTY strains was used to localize the origin of the cloned telomeric DNA by in situ hybridization to the tip of the long arm of chromosome 7.

A BamHI family of highly repeated DNA sequences of Nicotiana tabacum

HRS60.1, a monomer unit (184 bp) of a highly repeated nuclear DNA sequence of Nicotiana tabacum, has been cloned and sequenced. Following BamHI digestion of tobacco DNA, Southern hybridization with HRS60.1 revealed a ladder of hybridization bands corresponding to multiples of the basic monomer unit. If the tobacco DNA was digested with restriction endonucleases which have no target site in HRS60.1, the larger part of DNA homologous to HRS60.1 remained as uncleaved "relic" DNA. These results suggest a tandem arrangement of this DNA repeat unit. Four other clones of tobacco nuclear DNA cross-hybridized with HRS60.1, thus forming a "HRS60-family". Sequencing their inserts has shown their strong mutual homology. HRS60-family comprised about 2% of the nuclear genome of N. tabacum. Computer comparisons with other tandem plant-repeated DNA sequences could not detect any other homologous sequence.

Genome specific, highly repeated sequences of Hordeum vulgare: cloning, sequencing and squash dot test

Highly repeated sequences of nuclear DNA from barley Hordeum vulgare (L.) variety 'Erfa' were cloned. Several clones containing barley specific repeated DNA were analysed by sequence analysis and Southern blot hybridization. The investigated repeats differ from each other in their length, sequence and redundancy. Their length ranges from 36 bp to about 180 bp. The repeats are AT-rich and differ widely in their redundancy within the barley genome. Southern analysis showed that the repeats belong to different repetition complexes. The possibility for utilizing these clones as probes for simple and fast genome analysis is demonstrated in squash dot experiments.

Identification of a dispersed MboI repeat family in five higher plant genomes

Digestion of nuclear DNAs of five plants, namely Cucurbita maxima (red gourd), Trichosanthes anguina (snake gourd), Cucumis sativus (cucumber), Cajanus cajan (pigeon pea) and Phaseolus vulgaris (french bean) with the restriction endonuclease MboI yielded discrete size classes with molecular weights in the range of 0.5 to 5 kbp. The MboI digestion pattern of Cot 0.1 DNA in french bean is comparable with that of total DNA, indicating that these bands represented highly repeated DNA sequences. Cleavage of the DNAs with varying amounts of MboI indicated the dispersed nature of the repeat families. Southern hybridization studies using french bean highly repetitive DNA as a probe indicated more homology with repeats of pigeon pea and less homology with red gourd, snake gourd and cucumber repeats.

Distribution of telomere-associated sequences on natural chromosomes in Saccharomyces cerevisiae

Pulsed-field gel electrophoresis was used to examine the distribution of telomere-associated sequences on individual chromosomes in four strains of Saccharomyces cerevisiae. The pattern of X and Y' distribution was different for each strain. At least one chromosome in each strain lacked Y', and in some strains, chromosome I, the smallest yeast chromosome, lacked detectable amounts of both X and Y'.

Distribution of telomere-associated sequences on natural chromosomes in Saccharomyces cerevisiae

Pulsed-field gel electrophoresis was used to examine the distribution of telomere-associated sequences on individual chromosomes in four strains of Saccharomyces cerevisiae. The pattern of X and Y' distribution was different for each strain. At least one chromosome in each strain lacked Y', and in some strains, chromosome I, the smallest yeast chromosome, lacked detectable amounts of both X and Y'.

Isolation of a higher eukaryotic telomere from Arabidopsis thaliana

We have developed a method for constructing genomic libraries enriched for telomeric DNA sequences, enabling the isolation of telomeres from higher eukaryotic organisms with large chromosomes. The method was used to clone telomeric DNA sequences from the flowering plant Arabidopsis thaliana. A. thaliana telomeres are composed primarily of tandemly repeated blocks of the sequence 5'-CCCTAAA-3' and are heterogeneous in size. Genomic sequences that cross-hybridize at high stringency with A. thaliana telomeric repeats are present in other higher plants. In Zea mays (corn), these cross-hybridizing sequences are located at the telomeres. In addition, the A. thaliana telomeric repeats cross-hybridize at low stringency to genomic sequences located at the telomeres of human chromosomes.