Highly repeated DNA sequences in three species of the genus Pteropus (Megachiroptera, Mammalia)

Bat genomes are characterised by an A-T richness and by a small C-value compared with other mammalian groups. It has been suggested that the small C-value is mainly due to the lack of repetitive DNA sequences. However, little information about repetitive DNA sequences in this mammalian group is available at the molecular level. Here we describe a PstI family of repetitive DNA sequences present in three species of the genus Pteropus. These repetitive sequences are 54.97% G-C rich, organised in tandem and with a unit length of 744 bp. Methylation analysis indicates that some of the CCGG target sites present in these repetitive DNA sequences have methylated cytosines and that there are small differences in the methylation pattern between species. Several features of this family of repetitive sequences suggest that they evolved by concerted evolution.     

Distribution of repetitive DNA sequences in eubacteria and application to fingerprinting of bacterial genomes.

Dispersed repetitive DNA sequences have been described recently in eubacteria. To assess the distribution and evolutionary conservation of two distinct prokaryotic repetitive elements, consensus oligonucleotides were used in polymerase chain reaction [PCR] amplification and slot blot hybridization experiments with genomic DNA from diverse eubacterial species. Oligonucleotides matching Repetitive Extragenic Palindromic [REP] elements and Enterobacterial Repetitive Intergenic Consensus [ERIC] sequences were synthesized and tested as opposing PCR primers in the amplification of eubacterial genomic DNA. REP and ERIC consensus oligonucleotides produced clearly resolvable bands by agarose gel electrophoresis following PCR amplification. These band patterns provided unambiguous DNA fingerprints of different eubacterial species and strains. Both REP and ERIC probes hybridized preferentially to genomic DNA from Gram-negative enteric bacteria and related species. Widespread distribution of these repetitive DNA elements in the genomes of various microorganisms should enable rapid identification of bacterial species and strains, and be useful for the analysis of prokaryotic genomes.     

Possible repetitive DNA markers for Eusorghum and Parasorghum and their potential use in examining phylogenetic hypotheses on the origin of Sorghum species

Genomic structures of two major species in section Eusorghum (Sorghum), Sorghum bicolor and Sorghum halepense, and their phylogenetic relationships with a species in section Parasorghum, Sorghum versicolor, were studied by using cloned repetitive DNA sequences from the three species. Of the five repetitive DNA clones isolated from S. bicolor and S. halepense, four produced qualitatively similar hybridization patterns with detectable variations in copy numbers of some of the restriction fragments on the Southern blots of the two genomic DNAs. One clone was shown to be diagnostic for S. halepense. Molecular analysis at the DNA level indicates that S. bicolor and S. halepense have similar but not identical genomes, consonant with differences in karyotypes, meiotic chromosome behaviors, morphology, and physiology of the species. In addition to five repetitive clones isolated from S. bicolor and S. halepense, eight more sequences were cloned from S. versicolor. Nine clones were found to be specific for either S. bicolor and S. halepense or S. versicolor. The remaining four had a moderate to strong homology with sequences present in all Sorghum species studied. We speculate that the genome in the common ancestor of Sorghum has differentiated to give rise to genomes of at least three major chromosome sizes; large, medium, and small, as seen at present. Amplifications, eliminations, rearrangements, and new syntheses of repetitive sequences may have been involved in genome differentiation of these species. The results also suggest that the S. versicolor genome has strongly diverged from the genomes of the two species in section Eusorghum.     

Single-copy sequence homology among the GC-richest isochores of the genomes from warm-blooded vertebrates

We have hybridized a human DNA fraction corresponding to the GC-richest and gene-richest isochore family, H3, on compositional fractions of DNAs from 12 mammalian species and three avian species, representing eight and three orders, respectively. Under conditions in which repetitive sequences are competed out, the H3 isochore probe only or predominantly hybridized on the GC-richest fractions of main-band DNA from all the species investigated. These results indicate that single-copy sequences from the human H3 isochores share homology with sequences located in the compositionally corresponding compartments of the vertebrate genomes tested. These sequences are likely to be essentially formed by conserved coding sequences. The present results add to other lines of evidence indicating that isochore patterns are highly conserved in warm-blooded vertebrate genomes. Moreover, they refine recent reports (Sabeur et al., 1993; Kadi et al., 1993), and correct them in some details and also in demonstrating that the shrew genome does not exhibit the general mammalian pattern, but a special pattern.Correspondence to: G. Bernardi     

Disparate molecular evolution of two types of repetitive DNAs in the genome of the grasshopper Eyprepocnemis plorans

Wide arrays of repetitive DNA sequences form an important part of eukaryotic genomes. These repeats appear to evolve as coherent families, where repeats within a family are more similar to each other than to other orthologous representatives in related species. The continuous homogenization of repeats, through selective and non-selective processes, is termed concerted evolution. Ascertaining the level of variation between repeats is crucial to determining which evolutionary model best explains the homogenization observed for these sequences. Here, for the grasshopper Eyprepocnemis plorans, we present the analysis of intragenomic diversity for two repetitive DNA sequences (a satellite DNA (satDNA) and the 45S rDNA) resulting from the independent microdissection of several chromosomes. Our results show different homogenization patterns for these two kinds of paralogous DNA sequences, with a high between-chromosome structure for rDNA but no structure at all for the satDNA. This difference is puzzling, considering the adjacent localization of the two repetitive DNAs on paracentromeric regions in most chromosomes. The disparate homogenization patterns detected for these two repetitive DNA sequences suggest that several processes participate in the concerted evolution in E. plorans, and that these mechanisms might not work as genome-wide processes but rather as sequence-specific ones.     

Repetitive DNA variation and pivotal-differential evolution of wild wheats.

Several polyploid species in the genus Triticum contain a U genome derived from the diploid T. umbellulatum. In these species, the U genome is considered to be unmodified from the diploid based on chromosome pairing analysis, and it is referred to as pivotal. The additional genome(s) are considered to be modified, and they are thus referred to as differential genomes. The M genome derived from the diploid T. comosum is found in many U genome polyploids. In this study, we cloned three repetitive DNA sequences found primarily in the U genome and two repetitive DNA sequences found primarily in the M genome. We used these to monitor variation for these sequences in a large set of species containing U and M genomes. Investigation of sympatric and allopatric accessions of polyploid species did not show repetitive DNA similarities among sympatric species. This result does not support the idea that the polyploid species are continually exchanging genetic information through introgression. However, it is also possible that repetitive DNA is not a suitable means of addressing the question of introgression. The U genomes of both diploid and polyploid U genome species were similar regarding hybridization patterns observed with U genome probes. Much more variation was found both among diploid T. comosum accessions and polyploids containing M genomes. The observed variation supports the cytogenetic evidence that the M genome is more variable than the U genome. It also raises the possibility that the differential nature of the M genome may be due to variation within the diploid T. comosum, as well as among polyploid M genome species and accessions.     

Isolation of binary species-specific PCR-based markers and their value for diagnostic applications

Representational difference analysis (RDA), a technique for the isolation of differences between highly similar complex genomes, was employed for isolation of species-specific markers. These markers can be easily adapted for a high throughput PCR-based assay in which multiple specimens can be simultaneously identified based on the presence/absence of amplification products. One of the important features of RDA performed on genomes of different species (interspecific RDA) is its ability to preferentially isolate families of repetitive sequences that are unique to one of the compared genomes. Such families of repetitive DNA are homoplasy-free characters that can be used for cost-efficient, mass identification of specimens in a variety of situations ranging from mark-recapture studies to screenings of egg or larval stages.     

Isolation of A/D and C genome specific dispersed and clustered repetitive DNA sequences from Avena sativa.

DNA gel-blot and in situ hybridization with genome-specific repeated sequences have proven to be valuable tools in analyzing genome structure and relationships in species with complex allopolyploid genomes such as hexaploid oat (Avena sativa L., 2n = 6x = 42; AACCDD genome). In this report, we describe a systematic approach for isolating genome-, chromosome-, and region-specific repeated and low-copy DNA sequences from oat that can presumably be applied to any complex genome species. Genome-specific DNA sequences were first identified in a random set of A. sativa genomic DNA cosmid clones by gel-blot hybridization using labeled genomic DNA from different Avena species. Because no repetitive sequences were identified that could distinguish between the A and D gneomes, sequences specific to these two genomes are refereed to as A/D genome specific. A/D or C genome specific DNA subfragments were used as screening probes to identify additional genome-specific cosmid clones in the A. sativa genomic library. We identified clustered and dispersed repetitive DNA elements for the A/D and C genomes that could be used as cytogenetic markers for discrimination of the various oat chromosomes. Some analyzed cosmids appeared to be composed entirely of genome-specific elements, whereas others represented regions with genome- and non-specific repeated sequences with interspersed low-copy DNA sequences. Thus, genome-specific hybridization analysis of restriction digests of random and selected A. sativa cosmids also provides insight into the sequence organization of the oat genome.     

DNA sequences repaired at pachytene exhibit strong homology among distantly related higher plants

Moderately repetitive DNA sequences in Lilium (cv Enchantment) which undergo a meiotic-specific repair synthesis during pachytene (P-DNA) were previously shown to exist as families of very low internal sequence divergence. The present study concerns P-DNA sequence preservation among higher plants. The relative abundance of these sequences in a variety of plant species and their divergence relative to Enchantment P-DNA was determined through C₀t analysis and thermal denaturation of hybrid duplexes. Nearly all of the P-DNA sequence families of Enchantment were found to be present in the genomes of a number of monocot species and the dicot Vicia faba. Sequence content is highly conserved, with less than 6% divergence between Lilium and distantly related species such as Zea mays and Secale cereale. However, the number of repeats per P-DNA family varies considerably in different species, being particularly low among the Poales. P-DNA differs from most high thermal stability (HTS) sequence families of Enchantment which, although exhibiting a high degree of internal homology, are not present as repetitive DNA in the genomes of the other species examined. For most HTS families, the lack of internal divergence probably reflects their fairly recent introduction into the moderately repetitive DNA class, while P-DNA sequences represent evolutionarily ancient families which are the products of strong selective pressure for an indispensable meiotic function.     

A novel repetitive DNA sequence in the genus Oryza

Summary 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.     

Isolation and characterization of repetitive DNA sequences from Panax ginseng

Repetitive sequences constitute a significant component of most eukaryotic genomes, and the isolation and characterization of repetitive DNA sequences provide an insight into the organization and evolution of the genome of interest. We report the isolation and characterization of the major classes of repetitive sequences from the genome of Panax ginseng. The isolation of repetitive DNA from P. ginseng was achieved by the reannealing of chemically hydrolyzed (200 bp-1 kb fragments) and heat-denatured genomic DNA to low C(o)t value. The low C(o)t fraction was cloned, and fifty-five P. ginseng clones were identified that contained repetitive sequences. Sequence analysis revealed that the fraction includes repetitive telomeric sequences, species-specific satellite sequences, chloroplast DNA fragments and sequences that are homologous to retrotransposons. Two of the retrotransposon-like sequences are homologous to Ty1/ copia-type retroelements of Zea mays, and six cloned sequences are homologous to various regions of the del retrotransposon of Lilium henryi. The del retrotransposon-like sequences and several novel repetitive DNA sequences from P. ginseng were used to differentiate P. ginseng from P. quinquefolius, and should be useful for evolutionary studies of these disjunct species.     

Characterization of a major polymorphic tandem repeat in Mycobacterium tuberculosis and its potential use in the epidemiology of Mycobacterium kansasii and Mycobacterium gordonae.

In this study, the occurrence of repeated DNA sequences in the chromosome of Mycobacterium tuberculosis was investigated systematically. By screening a M. tuberculosis lambda gt-11 gene library with labeled total chromosomal DNA, five strongly hybridizing recombinants were selected, and these contained DNA sequences that were present in multiple copies in the chromosome of M. tuberculosis. These recombinants all contained repeated sequences belonging to a single family of repetitive DNA, which shares homology with a previously described repeated sequence present in recombinant pPH7301. Sequences analysis of pPH7301 showed the presence of a 10-bp sequence that was tandemly repeated and invariably separated by 5-bp unique spacer sequences. Southern blot analysis revealed that the majority of the repeated DNA in M. tuberculosis is composed of this family of repetitive DNA. Because the 10-bp repeats are slightly heterogeneous in sequence, we designated this DNA as a major polymorphic tandem repeat, MPTR. The presence of this repeated sequence in various other mycobacterial species was investigated. Among the MPTR-containing mycobacterial species the chromosomal location of the repetitive DNA is highly variable. The potential use of this polymorphism in the epidemiology of mycobacterioses is discussed.     

DNA sequence organization in the genome of Nicotiana tabacum

The genome of Nicotiana tabacum was investigated by DNA/DNA reassociation for its spectrum of DNA repetition components and pattern of DNA sequence organization. The reassociation of 300 nucleotide DNA fragments analyzed by hydroxyapatite chromatography reveals the presence of three major classes of DNA differing in reiteration frequency. Each class of DNA was isolated and characterized with respect to kinetic homogeneity and thermal properties on melting. These measurements demonstrate that the genome of N. tabacum has a 1C DNA content of 1.65 pg and that DNA sequences are represented an average of 12,400, 252, and 1 times each. — The organization of the DNA sequences in the N. tabacum genome was determined from the reassociation kinetics of long DNA fragments as well as S1 nuclease resistance and hyperchromicity measurements on DNA fragments after annealing to C₀t values at which only repetitive DNA sequences will reassociate. At least 55% of the total DNA sequences are organized in a short period interspersion pattern consisting of an alternation of single copy sequences, averaging 1400 nucleotides, with short repetitive elements approximately 300 nucleotides in length. Another 25% of the genome contains long repetitive DNA sequences having a minimal genomic length of 1500 nucleotides. These repetitive DNA sequences are much less divergent than the short interspersed DNA sequence elements. These results indicate that the pattern of DNA sequence organization in the tobacco genome bears remarkable similarity to that found in the genomes of most animal species investigated to date.     

Chromosomal location and distribution of As51 satellite DNA in five species of the genus Astyanax (Teleostei, Characidae, Incertae sedis)

Constitutive heterochromatin makes up a substantial portion of the genome of eukaryotes and is composed mainly of satellite DNA repeating sequences in tandem. Some satellite DNAs may have been derived from transposable elements. These repetitive sequences represent a highly dynamic component of rapid evolution in genomes. Among the genus Astyanax , the As51 satellite DNA is found in species that have large distal heterochromatic blocks, which may be considered as derived from a transposable DNA element. In the present study, As51 satellite DNA was mapped through in situ fluorescent hybridization in the chromosomes of five species of the genus. The possible roles of this type of saltatory DNA type in the genome of the species are discussed, along with its use for the phylogenetic grouping of the genus Astyanax , together with other shared chromosomal characters. However, the number of As51 clusters is presented as a homoplastic characteristic, thereby indicating evident genomic diversification of species with this type of DNA.     

Genomic repetitive DNA elements of Trypanosoma cruzi

Repetitive DNA sequences are interspersed throughout the genomes of mammals and other higher eukaryotes, and represent a substantial portion of the genome. Although it has been generally assumed that the redundant DNA is present only in the complex genomes of high order organisms, over the past few years a number of repetitive DNA sequences have been also detected in the protozoan parasite Trypanosoma cruzi. A compilation of the repetitive DNA sequences found in the T. cruzi genome is here presented by Jose Maria Requena, Manuel Carlos López and Carlos Alonso, who also speculate on their possible origin and functional implications regarding retrotransposition and gene regulation.     

Genome structure and divergence of nucleotide sequences in echinodermata

The arrangement of repetitive and single-copy DNA sequences has been studied in DNA of some species of Echinodermata — sea urchin, starfishes and sea-cucumber. Comparison of the reassociation kinetics of short and long DNA fragments indicates that the pattern of DNA sequence organization of all these species is similar to the so called Xenopus pattern characteristic of the genomes of most animals and plants. However, substantional variations have been found in the amount of repetitive nucleotide sequences in DNA of different species and in the length of DNA regions containing adjacent single-copy and repetitive sequences. Measurements of the size of S₁-nuclease resistant reassociated repetitive DNA sequences show a variability of ratios between long and short repetitive DNA sequences of different species. — The degree of divergence of short and long repetitive DNA sequences and single-copy DNA was studied by molecular hybridization of the sea urchin Strongylocentrotus intermedius ³H-DNA with the DNA of other species and by determination of the thermostability of the hybridized molecules so obtained. All three fractions of S. intermedius DNA contain sequences homologous to DNA of the other echinoderm species studied. The results obtained suggest that short repetitive DNA sequences are those which have been most highly conserved throughout the evolution of Echinodermata. A new hypothesis is proposed to explain the nature of the evolutionary changes in DNA sequence interspersion patterns.     

Studies on DNA sequences in the Osmundaceae

Summary Phylogenetic relationships ofOsmunda cinnamomea, O. claytoniana, andO. regalis were explored by means of DNA sequence comparisons. Hydroxyapatite thermal elution profiles of self-reassociated repetitive DNA fragments were very similar, indicating the absence of gross differences in the amount of recent amplification or addition of repetitive DNA in any of these three genomes. Interspecific DNA sequence comparisons showed, in contrast to our earlier interpretation, that repeated DNA sequences ofO. claytoniana are nearly equally diverged from those ofO. cinnamomea andO. regalis. Differences between repetitive sequences of the three species can be interpreted as reflecting amplification events which occurred subsequent to speciation. The data obtained suggest that the threeOsmunda species most likely arose more or less simultaneously from a common ancestor. These findings were verified in experiments with tracer DNA preparations enriched for single copy sequences. On the basis of the hybridization data presented here and of the fossil record, the rate of single copy sequence divergence in the ferns is comparable to that in the primates, although slower than that observed in other animal taxa. From this first evaluation of rates of DNA evolution in plants it would seem that the rates for plants and animals are roughly comparable. The evidence suggests that species divergence is accompanied by further reiteration of preexisting repeat sequences. The rate of addition of repetitive sequences probably is slower in ferns than in angiosperms. This difference might be attributable to the much larger effective generation time in ferns.     

Cotransposition of a highly repetitive DNA element with flanking sequences in the genome of the midgeChironomus thummi

Summary A family of highly repetitive DNA elements, the Cla-elements, is present in the genomes of the two sibling speciesChironomus th. thummi andCh. th. piger. These Cla-elements are organized in large tandem repetitive clusters as well as occuring as interspersed monomeric elements, in both subspecies. The analysis of a monomeric Cla-element and several kilobases of its flanking sequences fromCh. th. piger revealed that the short Cla-elements are cotransposed together with adjacent DNA. We found the same association of Cla-elements with specific flanking DNA in clones obtained from the rDNA ofCh. th. thummi and from nonribosomal Cla-DNA ofCh. th. piger. The Cla-element-flanking DNA is clearly also repetitive, but mainly of inter-spersed organization.