The molecular organisation of a B chromosome tandem repeat sequence fromBrachycome dichromosomatica

A high copy, tandemly repeated, sequence (Bd49) specific to the B chromosome and located near the centromere in Brachycome dichromosomatica was used to identify lambda genomic clones from DNA of a 3B plant. Only one clone of those analysed was composed entirely of a tandem array of the B-specific repeat unit. In other clones, the Bd49 repeats were linked to, or interspersed with, sequences that are repetitious and distributed elsewhere on the A and B chromosomes. One such repetitious flanking sequence has similarity to retrotransposon sequences and a second is similar to chloroplast DNA sequences. Of the four separate junctions analysed of Bd49-like sequence with flanking sequence, three were associated with the same A/T-rich region in Bd49 and the fourth was close to a 25 bp imperfect dyadic sequence. No novel B-specific sequences were detected within the genomic clones. Received: 31 December 1995; in revised form: 1 May 1996 / Accepted: 10 May 1996     

Evolution of Tandemly Repeated Sequences: What Happens at the End of an Array?

Tandemly repeated sequences are a major component of the eukaryotic genome. Although the general characteristics of tandem repeats have been well documented, the processes involved in their origin and maintenance remain unknown. In this study, a region on the paternal sex ratio (PSR) chromosome was analyzed to investigate the mechanisms of tandem repeat evolution. The region contains a junction between a tandem array of PSR2 repeats and a copy of the retrotransposon NATE, with other dispersed repeats (putative mobile elements) on the other side of the element. Little similarity was detected between the sequence of PSR2 and the region of NATE flanking the array, indicating that the PSR2 repeat did not originate from the underlying NATE sequence. However, a short region of sequence similarity (11/15 bp) and an inverted region of sequence identity (8 bp) are present on either side of the junction. These short sequences may have facilitated nonhomologous recombination between NATE and PSR2, resulting in the formation of the junction. Adjacent to the junction, the three most terminal repeats in the PSR2 array exhibited a higher sequence divergence relative to internal repeats, which is consistent with a theoretical prediction of the unequal exchange model for tandem repeat evolution. Other NATE insertion sites were characterized which show proximity to both tandem repeats and complex DNAs containing additional dispersed repeats. An ``accretion model' is proposed to account for this association by the accumulation of mobile elements at the ends of tandem arrays and into ``islands' within arrays. Mobile elements inserting into arrays will tend to migrate into islands and to array ends, due to the turnover in the number of intervening repeats. Received: 18 August 1997 / Accepted: 18 September 1998     

Toward closing rice telomere gaps: mapping and sequence characterization of rice subtelomere regions

Despite the collective efforts of the international community to sequence the complete rice genome, telomeric regions of most chromosome arms remain uncharacterized. In this report we present sequence data from subtelomere regions obtained by analyzing telomeric clones from two 8.8 × genome equivalent 10-kb libraries derived from partial restriction digestion with HaeIII or Sau3AI (OSJNPb HaeIII and OSJNPc Sau3AI). Seven telomere clones were identified and contain 25–100 copies of the telomere repeat (CCCTAAA)_n on one end and unique sequences on the opposite end. Polymorphic sequence-tagged site markers from five clones and one additional PCR product were genetically mapped on the ends of chromosome arms 2S, 5L, 10S, 10L, 7L, and 7S. We found distinct chromosome-specific telomere-associated tandem repeats (TATR) on chromosome 7 (TATR7) and on the short arm of chromosome 10 (TATR10s) that showed no significant homology to any International Rice Genome Sequencing Project (IRGSP) genomic sequence. The TATR7, a degenerate tandem repeat which is interrupted by transposable elements, appeared on both ends of chromosome 7. The TATR10s was found to contain an inverted array of three tandem repeats displaying an interesting secondary folding pattern that resembles a telomere loop (t-loop) and which may be involved in a protective function against chromosomal end degradation.Electronic Supplementary Material Supplementary material is available for this article at     

Genomic structure and sequence variation of a 3.3-kb repeat DNA element of the kangaroo rat, Dipodomys ordii

The genomic structure and sequence variation of a 3.3-kb repeat DNA element, representing 5% of the genome of the kangaroo rat Dipodomys ordii, has been investigated. Most of the repeats are arranged in tandem arrays of 50 kb or more. Thirteen randomly selected genomic clones have been mapped with twelve restriction enzymes. The frequency of sequence divergence in the genomic clones is 0.5%. The clone maps and the genomic structure studies have permitted the characterization of a number of variant members of the 3.3-kb repeat family. The genomic organization of the repeat resembles that for repeated DNAs found in large tandem arrays or satellites.     

The relationship between two tandem repeat families in rye heterochromatin

A bacterial artificial chromosome (BAC) library constructed from the short arm of rye (Secalecereale L.) chromosome 1R has been screened for clones containing copies of the pSc200 tandem repeat family, most abundant in rye subtelomeric heterochromatin. The molecular organization of the monomer array and adjacent sequences has been studied in BAC-126/C20. Digestion of the array with various restriction endonucleases reveals no higher-order organization. The DNA adjacent to the pSc200 array consists of different repeats, including retrotransposon derivatives and another tandemly repeated family, termed XbaI, with a monomer length of 576 bp, 475 of which show 82% similarity to the long terminal repeat of the known Cereba retrotransposon. Sequencing of the 13 kb long genomic region in BAC-126/C20 revealed a direct junction of the pSc200 and XbaI monomers. The arrays of both families terminate at the same AT-rich sequence CAAAAAT. Another recombination signal is the presence of palindromes in the close proximity to the junction site. The presence of microhomologies promotes the action of proteins involved in double-strand DNA break repair. To our knowledge, it is the first discovery of the direct junction of monomers that are longer than 100 bp and belong to different families of plant tandem repeats.     

The centromere region of Arabidopsis thaliana chromosome 1 contains telomere-similar sequences.

We describe the structure of an Arabidopsis thaliana genomic clone containing two classes of repetitive DNA elements derived from the centromere region of chromosome 1. One class is comprised of tandem arrays of a highly reiterated repeat containing degenerate telomere sequence motifs. Adjacent to these telomere-similar repeats we found a dispersed repetitive element reiterated approximately five times in the A. thaliana genome. The nucleotide sequence of the dispersed repeat is unusual, being extremely AT-rich and composed of numerous, overlapping repeat motifs.     

A Concertedly Evolving Region in Chironomus, Unique Within the Telomere

Chromosome terminal, complex repeats in the dipteran Chironomus pallidivittatus show rapid concerted evolution during which there is remarkably efficient homogenization of the repeat units within and between chromosome ends. It has been shown previously that gene conversion is likely to be an important component during these changes. The sequence evolution could be a result of different processes—exchanges between repeats in the tandem array as well as information transfer between units in different chromosomes—and is therefore difficult to analyze in detail. In this study the concerted evolution of a region present only once per chromosome, at the junction between the telomeric complex repeats and the subtelomeric DNA was therefore investigated in the two sibling species C. pallidivittatus and C. tentans. Material from individual microdissected chromosome ends was used, as well as clones from bulk genomic DNA. On the telomeric side of the border pronounced species-specific sequence differences were observed, the patterns being similar for clones of different origin within each species. Mutations had been transmitted efficiently between chromosomes also when adjoining, more distally localized DNA showed great differences in sequence, suggesting that gene conversion had taken place. The evolving telomeric region bordered proximally to subtelomeric DNA with high evolutionary constancy. More proximally localized, subtelomeric DNA evolved more rapidly and showed heterogeneity between species and chromosomes. Received: 24 September 1997 / Accepted: 24 November 1997     

Dynamics of 5S rDNA in the tilapia (Oreochromis niloticus) genome: repeat units,inverted sequences,pseudogenes and chromosome loci

In higher eukaryotes, the 5S ribosomal DNA (5S rDNA) is organized in tandem arrays with repeat units composed of a coding region and a non-transcribed spacer sequence (NTS). These tandem arrays can be found on either one or more chromosome pairs. 5S rDNA copies from the tilapia fish, Oreochromis niloticus, were cloned and the nucleotide sequences of the coding region and of the non-transcribed spacer were determined. Moreover, the genomic organization of the 5S rDNA tandem repeats was investigated by fluorescence IN SITU hybridization (FISH) and Southern blot hybridization. Two 5S rDNA classes, one consisting of 1.4-kb repeats and another one with 0.5-kb repeats were identified and designated 5S rDNA type I and type II, respectively. An inverted 5S rRNA gene and a 5S rRNA putative pseudogene were also identified inside the tandem repeats of 5S rDNA type I. FISH permitted the visualization of the 5S rRNA genes at three chromosome loci, one of them consisting of arrays of the 5S rDNA type I, and the two others corresponding to arrays of the 5S rDNA type II. The two classes of the 5S rDNA, the presence of pseudogenes, and the inverted genes observed in the O. niloticus genome might be a consequence of the intense dynamics of the evolution of these tandem repeat elements.     

Cytogenetic and molecular characterization of a highly repeated DNA sequence in the peach potato aphid Myzus persicae

Electrophoresis following digestion of Myzus persicae genomic DNA with HindIII showed the presence of a prominent band of approximately 200 bp whereas a faint electrophoretic band corresponding to DNA fragments of about 3000 bp was observed after digestion with ApaI. In situ digestion with restriction enzymes, followed by in situ nick translation, showed that ApaI targets are localized at the nucleolus organizer-bearing X telomeric region, whereas HindIII restriction sites are clustered in intercalary C-positive areas on the same X chromosome. Fluorescent in situ hybridization (FISH) carried out by using digoxygenin-labeled HindIII repeats as probe fully confirmed overlapping between the hybridization sites of this probe and the AT-rich intercalary heterochromatic bands on the X chromosome. These findings, together with published data, allow us to conclude that the M. persicae genome possesses three classes of C-positive heterochromatin: (i) a GC-rich argentophilic band located on one telomere of the X chromosome that contains ApaI targets; (ii) AT-rich intercalary bands located on the X chromosome containing clustered HindIII fragments; (iii) AT-rich telomeric bands, located on autosomes, consisting of HaeIII repeats. Molecular analysis has shown that the length of the HindIII repeat consensus sequence is 189 bp with an AT content of 67%. Southern blotting with HindIII monomers revealed a regular ladder of bands composed of multimers of basic length that are characteristic of satellite DNAs. The HindIII repeat displays other features typical of eukaryotic satellite arrays such as overlapping with heterochromatic bands and a high degree of sequence similarity among monomers (84%–94%). A similarity plot showed that sequences were particularly variable in the 50–100 bp region whereas they proved to be highly conservative in the first 50 bp, thus suggesting that this portion of the repeat might be functionally important. Received: 23 February 1999; in revised form: 21 July 1999 / Accepted: 28 July 1999     

Drosophila melanogaster does not share the telomeric repeat sequence of another invertebrate, Ascaris lumbricoides

Summary The DNA at the chromosomal termini of all eukaryotes from which it has been isolated contains a characteristic sequence motif consisting of tandem arrays of a regular or irregular repeat unit. These terminal repeats are thought to be essential for the maintenance of the chromosome ends. The sequences of the terminal repeats of all vertebrates studied thus far are identical and are similar enough to those of higher plants and some protozoans to cross-hybridize. However, previous studies have not detected cross-hybridization between the DNA of Drosophila mélanogaster and the terminal DNA sequences of any of several organisms tested. Recently, the first terminal DNA clone from a multicellular invertebrate, that of Ascaris lumbricoides, was reported also to consist of a tandem reiteration of a short sequence similar to those previously identified for other eukaryotes. Here I show that a probe for this sequence from A. lumbricoides fails to hybridize delectably to the DNA of D. melanogaster. Thus, in contrast to their conservation among vertebrates, the terminal chromosomal sequences appear not to be shared by all metazoan invertebrates.     

Characterisation of the telomeres at opposite ends of a 3 Mb Theileria parva chromosome.

Bacteriophage lambda clones containing Theileria parva genomic DNA derived from two different telomeres were isolated and the nucleotide sequences of the telomeric repeats and adjacent telomere-associated (TAS) DNA were determined. The T.parva telomeric repeat sequences, a tandem array of TTTTAGGG or TTTAGGG interspersed with a few variant copies, showed a high degree of sequence identity to those of the photosynthetic algae Chlamydomonas reinhardtii (97% identity) and Chlorella vulgaris (87.7% identity) and the angiosperm Arabidopsis thaliana (84.4% identity). Unlike most organisms which have been studied, no significant repetitive sequences were found in the nucleotide sequences of TAS DNA located centromere-proximal to the telomeric repeats. Restriction mapping and hybridisation analysis of lambda EMBL3 clones containing 16 kilobases of TAS DNA derived from one telomere suggested that they did not contain long regions of repetitive DNA. The cloned TAS DNAs were mapped to T.parva Muguga genomic SfiI fragments 8 and 20, which are located at opposite ends of the largest T.parva chromosome. A 126 bp sequence located directly centromere-proximal to the telomeric repeats was 94% identical between the two cloned telomeres. The conserved 126 bp sequence was present on all T.parva Muguga telomeric SfiI fragments.     

Organization of a Solatium brevidens repetitive sequence related to the TGRI subtelomeric repeats of Lycopersicon esculentum

A species-specific repetitive DNA fragment has been isolated from a genomic library of Solanum brevidens. Sequence analysis revealed a regular organization of three non-homologous subrepeats forming tandemly-arranged composite repetitive units. Interpretation of Southern hybridization patterns based on the known sequence data suggests that the isolated sequence element represents an abundant organization type, although the presence of simple tandem arrays of the subrepeats is also indicated. Seventy-four percent sequence similarity was found between one of the S. brevidens subrepeats (Sb4AX) and a satellite DNA (TGRI) localized as a subtelomeric repeat on almost all Lycopersicon esculentum chromosomes. Insitu hybridization indicated that, similarly to TGRI, the S. brevidens-specific repeats are located at the ends of the arms of several chromosomes. On the basis of the data obtained, a common ancestral sequence can be proposed for the tomato (TGRI) and the S. brevidens (Sb4AX) repeat however, the molecular organization of this element in these two species evolved in a basically different manner.     

Molecular cloning and characterization of novel centromeric repetitive DNA sequences in the blue-breasted quail (Coturnix chinensis,Galliformes)

A new family of centromeric highly repetitive DNA sequences was isolated from EcoRI-digested genomic DNA of the blue-breasted quail (Coturnix chinensis, Galliformes), and characterized by filter hybridization and chromosome in situ hybridization. The repeated elements were divided into two types by nucleotide length and chromosomal distribution; the 578-bp element predominantly localized to microchromosomes and the 1,524-bp element localized to chromosomes 1 and 2. The 578-bp element represented tandem arrays and did not hybridize to genomic DNAs of other Galliformes species, chicken (Gallus gallus), Japanese quail (Coturnix japonica) and guinea fowl (Numida meleagris). On the other hand, the 1,524-bp element was not organized in tandem arrays, and did hybridize to the genomic DNAs of three other Galliformes species, suggesting that the 1,524-bp element is highly conserved in the Galliformes. The 578-bp element was composed of basic 20-bp internal repeats, and the consensus nucleotide sequence of the internal repeats had homologies to the 41-42 bp CNM repeat and the XHOI family repeat of chicken. Our data suggest that the microchromosome-specific highly repetitive sequences of the blue-breasted quail and chicken were derived from a common ancestral sequence, and that they are one of the major and essential components of chromosomal heterochromatin in Galliformes species.     

Organization of Long Repeats of Sex-Chromosomal Heterochromatin in Common Vole Species

Two long repeats, MS3 and MS4, are predominantly located in sex-chromosomal heterochromatin in common vole species [1]. Their tandem arrangement was revealed by means of the PCR analysis of genomic DNAs of four Microtus species and by restriction mapping of clones selected from a M. rossiaemeridionalis genomic library. Several mobile elements proved to be incorporated in a monomeric unit of each repeat and amplified together with its other components. In addition, LINE inserts were found in MS4 tandem arrays. The copy number of both repeats per haploid genome was estimated at 100–300 for euchromatin and 20,000–40,000 for the M. rossiaemeridionalis genome. The repeats were assumed to be the major component of sex-chromosomal heterochromatin DNA.     

Complex telomere-associated repeat units in members of the genus Chironomus evolve from sequences similar to simple telomeric repeats.

The dipteran Chironomus tentans has complex tandemly repeated 350-bp DNA sequences at or near the chromosome ends. As in Drosophila melanogaster, short simple repeats with cytosines and guanines in different strands have never been observed. We were therefore interested in learning whether the Chironomus repeats could have evolved from simple sequence telomeric DNA, which might suggest that they constitute a functional equivalent. We screened for repeat units with evolutionarily ancient features within the tandem arrays and recovered two clones with a less-evolved structure. Sequence analysis reveals that the present-day 350-bp unit probably evolved from a simpler 165-bp unit through the acquisition of transposed sequences. The 165-bp unit contains DNA with a highly biased distribution of cytosine and guanine between the two strands, although with the ratios inverted in two minor parts of the repeat. It is largely built up of short degenerate subrepeats for which most of the sequence can be reconstructed. The consensus for the subrepeat sequence is similar to the simple telomeric repeat sequences of several kinds of eukaryotes. We propose that the present-day unit has evolved from telomeric, simple sequence, asymmetric DNA from which it has retained some original sequence features and possibly functions.     

Cross-hybridizing snake satellite, Drosophila, and mouse DNA sequences may have arisen independently

Previous reports have interpreted hybridization between snake satellite DNA and DNA clones from a variety of distant taxonomic groups as evidence for evolutionary conservation, which implies common ancestry (homology) and/or convergence (analogy) to produce the cross- hybridizing sequences. We have isolated 11 clones from a genomic library of Drosophila melanogaster, using a cloned 2.5-kb snake satellite probe of known nucleotide sequence. We have also analysed published sequence data from snakes, mice, and Drosophila. These data show that (1) all of the cross-hybridization between the snake, fly, and mouse clones can be accounted for by the presence of either of two tandem repeats, [GATA]n and [GACA]n and (2) these tandem repeats are organized differently among the different species. We find no evidence that these sequences are homologous apart from the existence of the simple repeat itself, although their divergence from a common ancestral sequence cannot be ruled out. The sequences contain a variety of homogeneous clusters of tandem repeats of CATA, GA, TA, and CA, as well as GATA and GACA. We suggest that these motifs may have arisen by a self-accelerating process involving slipped-strand mispairing of DNA. Homogeneity of the clusters might simply be the result of a rate of accumulation of tandem repeats that exceeds that of other mutations.      

Hypervariable 3′ UTR region of plant LTR-retrotransposons as a source of novel satellite repeats

The repetitive sequence PisTR-A has an unusual organization in the pea (Pisum sativum) genome, being present both as short dispersed repeats as well as long arrays of tandemly arranged satellite DNA. Cloning, sequencing and FISH analysis of both PisTR-A variants revealed that the former occurs in the genome embedded within the sequence of Ty3/gypsy-like Ogre elements, whereas the latter forms homogenized arrays of satellite repeats at several genomic loci. The Ogre elements carry the PisTR-A sequences in their 3′ untranslated region (UTR) separating the gag-pol region from the 3′ LTR. This region was found to be highly variable among pea Ogre elements, and includes a number of other tandem repeats along with or instead of PisTR-A. Bioinformatic analysis of LTR-retrotransposons mined from available plant genomic sequence data revealed that the frequent occurrence of variable tandem repeats within 3′ UTRs is a typical feature of the Tat lineage of plant retrotransposons. Comparison of these repeats to known plant satellite sequences uncovered two other instances of satellites with sequence similarity to a Tat-like retrotransposon 3′ UTR regions. These observations suggest that some retrotransposons may significantly contribute to satellite DNA evolution by generating a library of short repeat arrays that can subsequently be dispersed through the genome and eventually further amplified and homogenized into novel satellite repeats.     

Extensive Direct-Tandem Organization of a Long Repeat DNA Sequence on the Y Chromosome of Chinook Salmon (Oncorhynchus tshawytscha)

A long repetitive DNA sequence (OtY8) has been cloned from male chinook salmon and its genomic organization has been characterized. The repeat has a unit length of 8 kb and is present approximately 300 times per diploid male nucleus. All internal fragments within the 8-kb repeat segregate from father to son, suggesting that the entire repeat unit is located on the Y chromosome. The organization of this sequence into an 8-kb repeat unit is restricted to the Y chromosome, as are several male-specific repeat subtypes identified on the basis of restriction-site variation. The repeat possesses only weak internal sequence similarities, suggesting that OtY8 has not arisen by duplication of a smaller repeat unit, as is the case for other long tandem arrays found in eukaryotes. Based on a laddered pattern arising from partial digestion of genomic DNA with a restriction enzyme which cuts only once per repeat unit, this sequence is not dispersed on the Y chromosome but is organized as a head-to-tail tandem array. Pulse-gel electrophoresis reveals that the direct-tandem repeats are organized into at least six separate clusters containing approximately 12 to 250 copies, comprising some 2.4 Mb of Y-chromosomal DNA in total. Related sequences with nucleotide substitutions and DNA insertions relative to the Y-chromosomal fragment are found elsewhere in the genome but at much lower copy number and, although similar sequences are also found in other salmonid species, the amplification of the repeat into a Y-chromosome-linked tandem array is only observed in chinook salmon. The OtY8 repetitive sequence is genetically tightly associated with the sex-determination locus and provides an opportunity to examine the evolution of the Y chromosome and sex determination process in a lower vertebrate. Received: 4 April 1997 / Accepted: 22 July 1997