Evolutionary dynamics of satellite DNA family PIM357 in species of the genus Pimelia (Tenebrionidae,Coleoptera)

A large number of repeats of a satellite DNA (stDNA) family have been cloned and sequenced from species and populations of the genus Pimelia (Tenebrionidae, Coleoptera). The beetles were collected in the Canary Islands, Morocco, the Iberian Peninsula, and the Balearic Islands in order to analyze the evolutionary forces and processes acting on abundant stDNAs conserved at the genus level. This repetitive family is composed of an abundant A-T-rich stDNA, with basic units of 357 bp. All the sequences obtained showed similarity to the 22 repeat units of the PIM357 stDNA family described previously for six Iberian Pimelia species (Pons et al. 1997 ). An analysis based on similarity shows the presence of three different groups of sequences clearly in accordance with their geographical origin. One is composed of satellite sequences from Iberian and Balearic species, a second group from the Moroccan taxa, whereas the third one is from the Pimelia species endemic to the Canary Islands. The latter group shows higher nucleotide diversities for their stDNA sequences and a lack of relationship between transition stages to fixation and sequence divergence. Phylogeographic data of Canarian Pimelia show that the PIM357 stDNA family has persisted for more than 8 Myr and could probably be traced to the origin of the lineage. The data suggest that distinct demographic and phylogenetic patterns related to the colonization of the volcanic Canarian island chain account for particular evolutionary dynamics of the repeat DNA family in this group.     

Molecular and structural evolution of Citrus satellite DNA

Highly repeated satellite DNA (stDNA) of citric plants was characterized by cloning and sequencing 10–14 repeats of each plant (Citrus limon, C. sinensis, C. ichangensis, Poncirus trifoliata). The monomers are mostly 181 bp in length with a GC-content between 60% and 68% (significantly higher than the average GC-content of the citrus group genomes). Similarity among the repeats indicates that they belong to a satellite family that underwent species-specific modifications, which are reflected in the phylogenetic relationships. Curvature provoked by dA-stretches of the repeats analyzed by gel shifts revealed structural conservation, even though the nucleotide sequences vary among species, thereby probably supporting the heterochromatic structure of stDNA. We show that the species-specific modification of the satellite consensus involves changes in the position and number of dA tracts. The molecule shapes of satellite oligomeres predicted by computer modelling indicate a superhelical structure of the tandem repeats which is in a good agreement with the satellite sequence dendrogram. The contribution of DNA bending elements to the evolution of plant satellite repeats is discussed. Received: 27 November 2000 / Accepted: 12 January 2001     

Characterization and chromosome location of satellite DNA in the leaf beetle Chrysolina americana (Coleoptera, Chrysomelidae)

This paper is the first record of the satellite DNA of the specialized phytophagous genus Chrysolina. The satellite DNA of Chrysolina americana is organized in a tandem repeat of monomers 189 bp long, has a A + T content of 59.6 % and presents direct and inverted internal repeats. Restriction analysis of the total DNA with methylation sensitive enzymes suggests that this repetitive DNA is undermethylated. In situ hybridization with a biotinylated probe of the satellite DNA showed the pericentromeric localization of these sequences in all meiotic bivalents. The presence of this repetitive DNA in other species of the genus was also tested by Southern analysis. The results showed that this satellite DNA sequence is specific to the C. americana genome and has not been found in three other species of Chrysolina with a different choice of host plants than in the former. This revised version was published online in July 2006 with corrections to the Cover Date.     

Differences in the organization and chromosomal allocation of satellite DNA between the European long tailed house miceMus domesticus andMus musculus

We compared the organization of satellite DNA (stDNA) and its chromosomal allocation inMus domesticus and inMus musculus. The two stDNAs show similar restriction fragment profiles after digestion (probed withM. domesticus stDNA) with some endonucleases of which restriction sequences are present in the 230–240 bp repetitive unit of theM. domesticus stDNA. In contrast, EcoRI digestion reveals thatM. musculus stDNA lacks most of the GAATTC restriction sites, particularly at the level of the half-monomer. The chromosome distribution of stDNA (revealed by anM. domesticus stDNA probe) shows different patterns in theM. domesticus andM. musculus karyotypes, with about 60% ofM. domesticus stDNA retained in theM. musculus genome. It is particularly noteworthy that the pericentromeric regions ofM. musculus chromosomes 1 and X are totally devoid ofM. domesticus stDNA sequences. In both groups, the differences in energy transfer between the stDNA-bound fluorochromes Hoechst 33258 and propidium iodide suggest that AT-rich repeated sequences have a much more clustered array in theM. domesticus stDNA, as if they are organized in tandem repeats longer than those ofM. musculus. Considering the data as a whole, it seems likely that the evolutionary paths of the two stDNAs diverged after the generation of the ancestral 230–240 bp stDNA repetitive unit through the amplification, in theM. domesticus genome, of a family repeat which included the EcoRI GAATTC restriction sequence.     

Satellite DNA in the ant Messor structor (Hymenoptera, Formicidae).

This paper is the first record of the satellite DNA of Formicidae. The satellite DNA of the ant Messor structor is organized in a tandem repeat of monomers of 79 bp. Like satellite DNAs of other insects, it is AT rich and presents direct and inverted internal repeats. Restriction analysis of the total DNA with methylation-sensitive enzymes strongly suggests that this DNA is undermethylated. The presence of this repetitive DNA in other species of the genus Messor is also tested.     

PlantSat: a specialized database for plant satellite repeats

MOTIVATION: Tandemly organized repetitive sequences (satellite DNA) are widespread in complex eukaryotic genomes. In plants, satellite repeats often represent a substantial part of nuclear DNA but only a little is known about the molecular mechanisms of their amplification and their possible role(s) in genome evolution and function. Unfortunately, addressing these questions via characterization of general sequence properties of known satellite repeats has been hindered by a difficulty in obtaining a complete and unbiased set of sequence data for this analysis. This is mainly due to the presence of multiple entries of homologous sequences and of single entries that contain more than one repeated unit (monomer) in the public databases. RESULTS: We have established a computer database specialized for plant satellite repeats (PlantSat) that integrates sequence data available from various resources with supplementary information including repeat consensus sequences, abundances, and chromosomal localizations. The sequences are stored as individual repeat monomers grouped into families, which simplifies their computer analysis and makes it more accurate. Using this feature, we have performed a basic sequence analysis of the whole set of plant satellite repeats with respect to their monomer length and nucleotide composition. The analysis revealed several preferred length ranges of the monomers (approximately 165 bp and its multiples) and an over-representation of the AA/TT dinucleotide in the repeats. We have also detected an enrichment of satellite DNA sequences for the motif CAAAA that is supposed to be involved in breakage-reunion of repeated sequences.     

Complex structural features of satellite DNA sequences in the genus Pimelia (Coleoptera: Tenebrionidae): random differential amplification from a common 'satellite DNA library'

The major satellites of the nine species of the subgenera Pimelia s. str. and Amblyptera characterised in this paper are composed of longer monomers (500 and 700 bp) than those described previously in 26 Pimelia s. str. taxa (357 bp, a sequence called PIM357). Sequence analysis reveals partial similarity among these satellites and with the PIM357 monomers. The discrepancy between the phylogeny obtained based on three mitochondrial and two nuclear markers and that deduced from satellite DNA (stDNA) sequences suggests that the different Pimelia satellites were already present in a common ancestor forming what has been called a 'satellite DNA library'. Thus, the satellite profiles in the living species result from a random amplification of sequences from that 'library' during diversification of the species. However, species-specific turnover in the sequences has occurred at different rates. They have included abrupt replacements, a gradual divergence and, in other cases, no apparent change in sequence composition over a considerable evolutionary time. The results also suggest a common evolutionary origin of all these Pimelia satellite sequences, involving several rearrangements. We propose that the repeat unit of about 500 bp has originated from the insertion of a DNA fragment of 141 bp into the PIM357 unit. The 705-bp repeats have originated from a 32-bp direct duplication and the insertion of a 141-bp fragment in inverted orientation relative to a basic structure of 533 bp.     

Molecular cytogenetic characterization and chromosomal distribution of the satellite DNA in the genome of Oxya hyla intricata (Orthoptera: Catantopidae)

The genomic DNA of the grasshopper (Oxya hyla intricata) was subjected to electrophoresis after digestion with HaeIII, and the result showed two bands of highly repetitive DNA, approximately 200 and 400 bp in length. The 200-bp HaeIII-digested fragment was cloned and characterized by sequencing and fluorescence in situ hybridization (FISH). The results showed the presence of two distinct satellite DNA (stDNA) families: one consisting of a 169-bp repeated element having an A+T content of 60.9% and the other consisting of a 204-bp repeated element having an A+T content of 53.9%. No significant homology between the two stDNA families was observed. FISH showed that the chromosomal locations of these families are different from each other. The 169-bp element was located in the C-band-positive regions of the short arms of most of the chromosomes, whereas the 204-bp element was located in the centromeric regions of three chromosome pairs. These results imply that the origins of these two DNA families are different. The results of zoo-blot hybridization to the genomic DNA from four Oxya species, O. hyla intricata, O. japonica japonica, O. chinensis formosana, and O. yezoensis, suggest that the two stDNA families found in the present study are species-specific for O. hyla intricata.     

Sobo, a recently amplified satellite repeat of potato, and its implications for the origin of tandemly repeated sequences

Highly repetitive satellite DNA sequences are main components of heterochromatin in higher eukaryotic genomes. It is well known that satellite repeats can expand and contract dramatically, which may result in significant genome size variation among genetically related species. The origin of satellite repeats, however, is elusive. Here we report a satellite repeat, Sobo, from a diploid potato species, Solanum bulbocastanum. The Sobo repeat is mapped to a single location in the pericentromeric region of chromosome 7. This single Sobo locus spans approximately 360 kb of a 4.7-kb monomer. Sequence analysis revealed that the major part of the Sobo monomer shares significant sequence similarity with the long terminal repeats (LTRs) of a retrotransposon. The Sobo repeat was not detected in other Solanum species and is absent in some S. bulbocastanum accessions. Sobo monomers are highly homogenized and share >99% sequence identity. These results suggest that the Sobo repeat is a recently emerged satellite and possibly originated by a sudden amplification of a genomic region including the LTR of a retrotransposon and its flanking genomic sequences.     

Detection of satellite DNA in Palorus ratzeburgii: analysis of curvature profiles and comparison with Tenebrio molitor satellite DNA.

Very abundant and homogenous satellite DNA has been found in the flour beetle Palorus ratzeburgii, representing 40% of its genome. Sequencing of 14 randomly cloned satellite monomers revealed a conserved monomer length of 142 bp and an average A+T content of 68%. Sequence variation analysis showed that base substitutions, appearing with a frequency of 2.3%, are predominant differences among satellite monomers. The satellite sequence is unique without significant direct repeats and with only two potentially stable inverted repeats. After electrophoresis of satellite monomers on native polyacrylamide gel retarded mobilities characteristic for curved DNA molecules are observed. The curvature profiles and DNA helix axis trajectory are calculated on the basis of three different algorithms. These calculations predict that P ratzeburgii satellite DNA forms a left-handed solenoid superstructure. Comparison of described features with other satellite DNAs reveals some striking similarities with satellite DNA from related species Tenebrio molitor, which belongs to the same family of Tenebrionidae. Both satellites are very abundant and homogenous with the same, highly conserved monomer length, although there is no homology at the nucleotide level. Their monomers, as well as multimers, exhibit very similar retarded electrophoretic mobilities. The calculated curvature profiles predict two bend centers in monomers of each satellite, resulting in a model of left-handed solenoid superstructures of similar appearance.     

A subtelomeric satellite DNA family isolated from the genome of the dioecious plant Silene latifolia.

In an ongoing effort to trace the evolution of the sex chromosomes of Silene latifolia, we have searched for the existence of repetitive sequences specific to these chromosomes in the genome of this species by direct isolation from low-melting agarose gels of satellite DNA bands generated by digestion with restriction enzymes. Five monomeric units belonging to a highly repetitive family isolated from Silene latifolia, the SacI family, have been cloned and characterized. The consensus sequence of the repetitive units is 313 bp in length (however, high variability exists for monomer length variants) and 52.9% in AT. Repeating units are tandemly arranged at the subtelomeric regions of the chromosomes in this species. The sequence does not possess direct or inverted sequences of significant length, but short direct repeats are scattered throughout the monomer sequence. Several short sequence motives resemble degenerate monomers of the telomere repeat sequence of plants (TTTAGGG), confirming a tight association between this subtelomeric satellite DNA and the telomere repeats. Our approach in this work confirms that SacI satellite DNA sequences are among the most abundant in the genome of S. latifolia and, on the other hand, that satellite DNA sequences specific of sex chromosomes are absent in this species. This agrees with a sex determination system less cytogenetically diverged from a bisexual state than the system present in other plant species, such as R. acetosa, or at least a lesser degree of differentiation between the sex chromosomes of S. latifolia and the autosomes.     

Pericentric satellite DNA sequences in Pipistrellus pipistrellus (Vespertilionidae; Chiroptera)

This paper reports the molecular and cytogenetic characterization of a HindIII family of satellite DNA in the bat species Pipistrellus pipistrellus. This satellite is organized in tandem repeats of 418 bp monomer units, and represents approximately 3% of the whole genome. The consensus sequence from five cloned monomer units has an A-T content of 62.20%. We have found differences in the ladder pattern of bands between two populations of the same species. These differences are probably because of the absence of the target sites for the HindIII enzyme in most monomer units of one population, but not in the other. Fluorescent in situ hybridization (FISH) localized the satellite DNA in the pericentromeric regions of all autosomes and the X chromosome, but it was absent from the Y chromosome. Digestion of genomic DNAs with HpaII and its isoschizomer MspI demonstrated that these repetitive DNA sequences are not methylated. Other bat species were tested for the presence of this repetitive DNA. It was absent in five Vespertilionidae and one Rhinolophidae species, indicating that it could be a species/genus specific, repetitive DNA family.     

Higher-order repeats in the satellite DNA of the cave beetle Pholeuon proserpinae glaciale (Coleoptera: Cholevidae)

The present study characterizes the satellite DNA of the cave beetle Pholeuon proserpinae glaciale which represent about 3-5 % of its genome, and which is composed of monomers of 266 bp and 70.5 % A-T. Concerted evolution seems to act on a higher-order repeat, a dimer, composed of two types of 266-bp monomers that differ in three diagnostic sites. These dimers show a striking nucleotide identity (98.7 % similarity) suggesting strong homogenization processes. The presence of particular mutations shared by several dimers represents an early expansion of these types of repeats as proposed by the molecular drive model. Moreover, evidence of gene conversion tracts in P. proserpinae glaciale, which also could be the result of unequal sister chromatid exchange, would suggest that recombination is involved in the homogenization of stDNA sequences. The presence of a 17-bp-motif repeated six times, along another one of 31-bp repeated twice which also have embedded one 17-bp-motif, suggest that monomers have originated from those basic motifs.     

Structure Analysis of Two <Emphasis Type="Italic">Toxoplasma gondii</Emphasis> and <Emphasis Type="BoldItalic">Neospora caninum</Emphasis> Satellite DNA Families and Evolution of Their Common Monomeric Sequence

A family of repetitive DNA elements of approximately 350 bp—Sat350—that are members of Toxoplasma gondii satellite DNA was further analyzed. Sequence analysis identified at least three distinct repeat types within this family, called types A, B, and C. B repeats were divided into the subtypes B1 and B2. A search for internal repetitions within this family permitted the identification of conserved regions and the design of PCR primers that amplify almost all these repetitive elements. These primers amplified the expected 350-bp repeats and a novel 680-bp repetitive element (Sat680) related to this family. Two additional tandemly repeated high-order structures corresponding to this satellite DNA family were found by searching the Toxoplasma genome database with these sequences. These studies were confirmed by sequence analysis and identified: (1) an arrangement of AB1CB2 350-bp repeats and (2) an arrangement of two 350-bp-like repeats, resulting in a 680-bp monomer. Sequence comparison and phylogenetic analysis indicated that both high-order structures may have originated from the same ancestral 350-bp repeat. PCR amplification, sequence analysis and Southern blot showed that similar high-order structures were also found in the Toxoplasma-sister taxon Neospora caninum. The Toxoplasma genome database ( ) permitted the assembly of a contig harboring Sat350 elements at one end and a long nonrepetitive DNA sequence flanking this satellite DNA. The region bordering the Sat350 repeats contained two differentially expressed sequence-related regions and interstitial telomeric sequences.     

Beta satellite DNA: characterization and localization of two subfamilies from the distal and proximal short arms of the human acrocentric chromosomes.

beta satellite is a repetitive DNA family that consists of approximately 68-bp monomers tandemly repeated in arrays of at least several hundred kilobases. In this report we describe and characterize two subfamilies located exclusively on the human acrocentric chromosomes. The first subfamily is defined by a homogeneous approximately 2.0-kb higher-order repeat unit and is located primarily distal to the ribosomal RNA gene cluster, based both on fluorescence in situ hybridization to metaphase chromosomes and on filter hybridization analysis of translocation chromosomes isolated in somatic cell hybrids. In contrast, the second subfamily is located both distal and proximal to the ribosomal RNA gene cluster on the same acrocentric chromosomes. The DNA sequences of a number of monomers from these two subfamilies are compared to each other and to other beta satellite monomers to assess both inter- and intrasubfamily sequence relationships for these monomers.     

Detection of satellite DNA in Palorus ratzeburgii: Analysis of curvature profiles and comparison with Tenebrio molitor satellite DNA

Very abundant and homogenous satellite DNA has been found in the flour beetle Palorus ratzeburgii, representing 40% of its genome. Sequencing of 14 randomly cloned satelite monomers revealed a conserved monomer length of 142 bp and an average A+T content of 68%. Sequence variation analysis showed that base substitutions, appearing with a frequency of 2.3%, are predominant differences among satellite monomers. The satellite sequence is unique without significant direct repeats and with only two potentially stable inverted repeats. After electrophoresis of satellite monomers on native polyacrylamide gel retarded mobilities characteristic for curved DNA molecules are observed. The curvature profiles and DNA helix axis trajectory are calculated on the basis of three different algorithms. These calculations predict that P ratzeburgii satellite DNA forms a left-handed solenoid superstructure. Comparison of described features with other satellite DNAs reveals some striking similarities with satellite DNA from related species Tenebrio molitor, which belongs to the same family of Tenebrionidae. Both satellites are very abundant and homogenous with the same, highly conserved monomer length, although there is no homology at the nucleotide level. Their monomers, as well as multimers, exhibit very similar retarded electrophoretic mobilities. The calculated curvature profiles predict two bend centers in monomers of each satellite, resulting in a model of left-handed solenoid superstructures of similar appearance.     

Characterization of a 249-bp tandemly repetitive, satellite-like repeat in the translated portion of Balbiani ring c of Chironomus thummi.

A major part of Balbiani ring (BR)c DNA of Chironomus thummi consists of tandem 249-bp repeats which appear to be transcribed and translated into a polypeptide of very unusual composition. Whereas these 2549-bp repeats are evident by Southern blotting, sequence analysis reveals a finer tandemly repetitive substructure: more than half of the 249-bp repeat length consists of tandem 24-bp subrepeats , and these in turn may have been generated from even shorter sequences. Comparisons with partial BRb and BR1 sequences reveal that this hierarchically repetitive sequence structure is typical of BR genes. It resembles the structure of some satellite sequences, suggesting that mechanisms leading to satellite DNA evolution may also operate in the evolution of structural genes.     

Arrays of repetitive DNA elements in the largest chromosomes of Toxoplasma gondii.

A novel tandemly repeated DNA structure of Toxoplasma gondii that meets the requirements assigned for satellital DNA was characterized. A DNA fragment of 1002 bp contains two different elements of repetitive DNA families named ABGTg7 and ABGTg8.2. Both repeats are members of a more complex tandem structure where ABGTg7-like monomers can be arranged either as direct tandems or flanked by other related or non-related repeats. Pulse-field gel electrophoresis analysis showed that these repeats hybridize with the largest T. gondii chromosomes. Bal31 sensitivity assays indicated that these elements are located near the telomeres and along other regions too. Five genomic lambda phages were isolated and two different completed clusters of the repeated structure were analyzed.     

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.