Characterization of the satellitome in lower vascular plants: the case of the endangered fern Vandenboschia speciosa.

BACKGROUND AND AIMS: Vandenboschia speciosa is a highly vulnerable fern species, with a large genome (10.5 Gb). Haploid gametophytes and diploid sporophytes are perennial, can reproduce vegetatively, and certain populations are composed only of independent gametophytes. These features make this fern a good model: (1) for high-throughput analysis of satellite DNA (satDNA) to investigate possible evolutionary trends in satDNA sequence features; (2) to determine the relative contribution of satDNA and other repetitive DNAs to its large genome; and (3) to analyse whether the reproduction mode or phase alternation between long-lasting haploid and diploid stages influences satDNA abundance or divergence. METHODS: We analysed the repetitive fraction of the genome of this species in three different populations (one comprised only of independent gametophytes) using Illumina sequencing and bioinformatic analysis with RepeatExplorer and satMiner. KEY RESULTS: The satellitome of V. speciosa is composed of 11 satDNA families, most of them showing a short repeat length and being A + T rich. Some satDNAs had complex repeats composed of sub-repeats, showing high similarity to shorter satDNAs. Three families had particular structural features and highly conserved motifs. SatDNA only amounts to approx. 0.4 % of its genome. Likewise, microsatellites do not represent more than 2 %, but transposable elements (TEs) represent approx. 50 % of the sporophytic genomes. We found high resemblance in satDNA abundance and divergence between both gametophyte and sporophyte samples from the same population and between populations. CONCLUSIONS: (1) Longer (and older) satellites in V. speciosa have a higher A + T content and evolve from shorter ones and, in some cases, microsatellites were a source of new satDNAs; (2) the satellitome does not explain the huge genome size in this species while TEs are the major repetitive component of the V. speciosa genome and mostly contribute to its large genome; and (3) reproduction mode or phase alternation between gametophytes and sporophytes does not entail accumulation or divergence of satellites.

The repetitive DNA content of eukaryotic genomes.

Eukaryotic genomes are composed of both unique and repetitive DNA sequences. These latter form families of different classes that may be organized in tandem or may be dispersed within genomes with a moderate to high degree of repetitiveness. The repetitive DNA fraction may represent a high proportion of a particular genome due to correlation between genome size and abundance of repetitive sequences, which would explain the differences in genomic DNA contents of different species. In this review, we analyze repetitive DNA diversity and abundance as well as its impact on genome structure, function, and evolution.

A satellite DNA evolutionary analysis in the North American endemic dioecious plant Rumex hastatulus (Polygonaceae).

We studied the evolution of RAE180 satellite DNA family in the North American endemic dioecious plant Rumex hastatulus. In this species, the Texas race is characterized by a single XX/XY sex chromosome system, whereas the North Carolina race has evolved a derived complex XX/XY(1)Y(2) sex chromosome system. RAE180 repeats were autosomic and poorly represented (2 × 10(-4)% of the genome) with no differences between individuals of different genders or different races of R. hastatulus. In fact, the sex chromosomes of the North Carolina race are still euchromatic, and they have not accumulated satellite DNA sequences, which contrasts with that occurring in the rest of dioecious XX/XY(1)Y(2) Rumex species. In R. hastatulus, we detected the existence of three RAE180 subfamilies. Notwithstanding, while in the Texas race the TX1/NC1 subfamily is the most frequent, the TX2/NC2 subfamily is the most abundant in the North Carolina race. Additionally, the third, less represented subfamily (TX3/NC3) appears currently as relict sequences in both genomes. A common feature of RAE180 satellite is the sudden replacement of one sequence variant by another in different species (or populations as in R. hastatulus races). Thus, the phylogenetic analysis of RAE180 repeats from six dioecious Rumex species supports the "library" hypothesis. According to this hypothesis, we assume that a set of divergent RAE180 variants were present in the ancestral genome of dioecious Rumex species, from which novel tandem arrays originated by the amplification of different variants in different lineages. Differential levels of RAE180 satellite DNA amplification in each lineage, at different evolutionary times, and in different chromosomal positions gave rise to differential patterns of sequence evolution.

Effect of location, organization, and repeat-copy number in satellite-DNA evolution.

Here, we analyze the evolutionary dynamics of a satellite-DNA family in an attempt to understand the effect of factors such as location, organization, and repeat-copy number in the molecular drive process leading to the concerted-evolution pattern found in this type of repetitive sequences. The presence of RAE180 satellite-DNA in the dioecious species of the plant genus Rumex is a noteworthy feature at this respect, as RAE180 satellite repeats have accumulated differentially, showing a distinct distribution pattern in different species. The evolution of dioecious Rumex gave rise to two phylogenetic clades: one clade composed of species with an ancestral XX/XY sex chromosome system and a second, derived clade of species with a multiple sex-chromosome system XX/XY(1)Y(2). While in the XX/XY dioecious species, the RAE180 satellite-DNA is located only in a small autosomal locus, the RAE180 repeats are present also in a small autosomal locus and additionally have been massively amplified in the Y chromosomes of XX/XY(1)Y(2) species. Here, we have found that the RAE180 repeats of the autosomal locus of XX/XY species are characterized by intra-specific sequence homogeneity and inter-specific divergence and that the comparison of individual nucleotide positions between related species shows a general pattern of concerted evolution. On the contrary, both in the autosomal and the Y-linked loci of XX/XY(1)Y(2) species, ancestral variability has remained with reduced rates of sequence homogenization and of evolution. Thus, this study demonstrates that molecular mechanisms of non-reciprocal exchange are key factors in the molecular drive process; the satellite DNAs in the non-recombining Y chromosomes show low rates of concerted evolution and intra-specific variability increase with no inter-specific divergence. By contrast, freely recombining loci undergo concerted evolution with genetic differentiation between species as occurred in the autosomal locus of XX/XY species. However, evolutionary periods of rapid sequence change might alternate with evolutionary periods of stasis with variability remaining by the reduced action of molecular mechanisms of non-reciprocal exchange as occurred in XX/XY(1)Y(2) species, which could depend on repeat-copy number and the processes involved in their amplification.

Characterization of RUSI, a telomere-associated satellite DNA, in the genus Rumex (Polygonaceae).

A satellite-DNA family (RUSI) has been isolated and characterized in Rumexinduratus Boiss and Reuter (Polygonaceae), an Iberian endemic polygamous sorrel. The RUSI repeats are 170 bp in length and approximately 68% AT-rich containing different variants of degenerate telomere motifs--(TT)(n)AN(GG)(n) -, a typical feature of subtelomeric DNA repeats adjacent to telomeres, which have been referred to as telomere-associated sequences or TASs. In fact, fluorescent in situhybridization showed that this satellite DNA is located in subtelomeric positions of most of the chromosomes of R. induratus, with some centromeric loci. PCR and Southern-blot hybridization assays for sequence conservation in the genus Rumex, indicated that the RUSI sequences are restricted to the genomes of R. induratus and R. scutatus, both species of the section Scutati, suggesting that they are recently evolved. Sequence variation within the two species is high (mean value of sequence differences between repeats of 15% for R. induratus and 7.5% for R. scutatus) and the degree of sequence differentiation between species is low with no species-specific variants, postulated to be due to slowed rates of spreading of sequence variants by molecular homogenizing mechanisms. Characteristics of RUSI sequences are discussed in the light of their chromosomal location and analyzed for their evolutionary and phylogenetic implications.

The centromeric satellite of the wedge sole (Dicologoglossa cuneata, Pleuronectiformes) is composed mainly of a sequence motif conserved in other vertebrate centromeric DNAs.

Here, a new satellite-DNA family is isolated and characterized from wedge sole, Dicologoglossa cuneata Moreau, 1881 (Pleuronectiformes), a fish having a small genome. This satellite-DNA family of sequences was isolated by conventional cloning after digestion of genomic DNA with the DraI restriction enzyme. Repeat units are 171 bp in length with a high AT content (63%). Several runs of consecutive adenines and thymines were found, and concomitantly computer analyses revealed that these regions are prone to acquire stable sequence-directed curvature. Especially remarkable is that the DraI sequences are composed almost entirely of the repetition of up to fourteen 9-bp motifs (T/C)GTC(A/C)AAAA similar to other vertebrate centromeric satellite-DNA sequences. In fact, we demonstrate the origin of this satellite through duplication of this motif plus the addition of a stretch of cytosines. The centromeric location and the presence in this satellite-DNA sequence of not only different vertebrate motifs (CENP-B box, pJalpha) but also others such as the CDEIII motif of Saccharomyces cerevisiae reveal a possible role in centromere function. All these characteristics provide important information on the origin, function, and the evolution of the centromeric satellite DNAs in wedge sole.

The controversial telomeres of lily plants.

The molecular structure of the exceptional telomeres of six plant species belonging to the order Asparagales and two species of the order Liliales was analyzed using Southern blot and fluorescence in situ hybridization. Three different situations were found, namely: i) In the two Liliales species, Tulipa australis (Liliaceae) and Merendera montana (Colchicaceae), the chromosome ends display hybridization signals with oligonucleotides resembling telomere repeats of both plants (TTTAGGG)n and vertebrates (TTAGGG)n. ii) Asparagales species such as Phormium tenax (Hemerocallidaceae), Muscari comosum (Hyacinthaceae), Narcissus jonquilla (Amaryllidaceae) and Allium sativum (Alliaceae) lack both the plant telomere repeats and the vertebrate telomere repeats. iii) Two other Asparagales species, Aloe vera (Asphodelaceae) and an Iris hybrid (Iridaceae), display positive hybridization with the vertebrate telomere repeats but not with the plant telomere repeats. Southern blot hybridization revealed concurring results. On this basis, the composition of the telomere structure in this plant group is discussed.

The molecular diagnosis of Marteilia refringens and differentiation between Marteilia strains infecting oysters and mussels based on the rDNA IGS sequence.

Marteilia refringens is a paramyxean parasite which infects the flat oyster Ostrea edulis and mussels (Mytilus galloprovincialis), where it has been attributed to a separate species, Marteilia maurini, by several authors. Doubts persist though as to the existence or not of two species of Marteilia in Europe. We have devised a molecular method for the diagnosis of M. refringens based on 358 bp nested-PCR of the rDNA intergene spacer (rDNA IGS) which is capable of detecting 0.5 fg of M. refringens DNA. Molecular characterization of this spacer indicates that the Marteilia parasites which infect oysters and mussels are two different strains of the same species.

A heterochromatic satellite DNA is highly amplified in a single chromosome of Muscari (Hyacinthaceae).

We examined the composition and evolution of a large heterochromatic region present in the genomes of certain species of the genus Muscari (Hyacinthaceae). We found that in Muscari comosum this heterochromatic region is composed mainly of a satellite DNA family, which we named MCSAT. Molecular analyses and in situ hybridization revealed that, through the evolution of Muscari species, the MCSAT sequences have been progressively amplified in several species of the genus, such as M. matritensis and M. dionysicum, attaining enormous amplification in the genome of M. comosum. We discuss the characteristics of this satellite DNA family, which, being exclusively amplified in one chromosome pair of M. comosum, constitute the major exception to the equilocal model of satellite DNA and heterochromatin distribution. Also, we discuss the possibility that the amplification of these sequences in a single chromosome could have contributed to a progressive increase in the asymmetry of the karyotypes in Muscari species.

Chromosomal location and evolution of a satellite DNA family in seven sturgeon species.

The Hind III satellite DNA family, isolated from the Acipenser naccarii genome, was used as a probe for fluorescent in-situ hybridization (FISH) on the karyotype of seven sturgeon species, six belonging to the genus Acipenser and one to Huso. All species except one (A. sturio) exhibit from 8 to 80 chromosome hybridization signals, mainly localized at the pericentromeric regions. Eight chromosomes with weak hybridization signals are present in H. huso and A. ruthenus, which are characterized by a karyotype with about 120 chromosomes. The species with 240-260 chromosomes, A. transmontanus, A. naccarii, A. gueldenstaedtii, and A. baerii, show from 50 to 80 signals, prevalently localized around centromeres. Moreover, A. transmontanus and A. gueldenstaedtii show from 4 to 8 chromosomes with a double signal. The phylogenetic and evolutionary relationships among sturgeon species are discussed on the basis of number and morphology of signal-bearing chromosomes and on the localization of signals.

The molecular phylogeny of the Sparidae (Pisces, Perciformes) based on two satellite DNA families.

In this study, the phylogenetic relationships and which the taxonomic status of the species belonging to the Sparidae family (Pisces: Perciformes) are analysed and revised. This study includes species of this family that are distributed by the North-eastern Atlantic and Mediterranean coasts, is based on the analysis of two satellite DNA families. While one satellite DNA, the centromeric EcoRI family, extends to all the species analysed, the other, the subtelomeric DraI family, is restricted to only six of the 16 species studied. Based on phylogenetic use of these two markers, we conclude that the Sparidae family is composed by two major lineages: one comprising the species of the genera Sparus, Diplodus, Lithognathus, Boops, Sarpa and Spondyliosoma, and one species of Pagellus (P. bogaraveo); and the other lineage is comprised of the species of Pagrus and Dentex, and one species of Pagellus (P. erythrinus). This classification is consistent across the two markers used and clearly contradicts previous morphological phylogenies based mainly on dentition. In addition, the current status and the phylogenetic position of some of the species analysed (i.e. species of Pagrus, Dentex and Pagellus) are not supported by our analyses. Finally, we discuss the value of the morphological characters used until now for the classification of this group of fish.

Molecular characterization of the ribosomal RNA gene region of Perkinsus atlanticus: its use in phylogenetic analysis and as a target for a molecular diagnosis.

Due to their widespread distribution and virulence, protozoan species of the genus Perkinsus are especially worrisome parasites for shellfish farmers. In the present paper, we investigate the organization and the structural features of the nuclear ribosomal genes of Perkinsus atlanticus as well as the use of DNA sequence information from this region for phylogenetic analyses. This information has been useful, further, for the development of a diagnostic test based on the amplification by the polymerase chain reaction (PCR) technique. We have isolated a high-copy DNA sequence in this species, and, after its characterization, we have determined that it corresponds to the ribosomal RNA (rRNA) genes 28S-5S-18S and the intergenic spacers. By comparing the complete sequence of the 5S rRNA gene and a partial sequence of the 18S rRNA gene of P. atlanticus with the sequences of those genes in other Alveolates, we have found additional support for the hypothesis that Perkinsus is more closely related to species of Dinoflagellata than to species of Apicomplexa. The intergenic spacer sequence between the 5S and the 18S rRNA genes was used to design a pair of primers to be used as a PCR-based diagnostic test.

Organization of repetitive DNA sequences at pachytene chromosomes of gilthead seabream Sparus aurata (Pisces, Perciformes).

A method of preparing two-dimensional surface spreads of fish synaptonemal complexes (SCs) associated with fluorescent in-situ hybridization is described. This technique permits a novel approach to the analysis of chromatin organization and the construction of physical maps at meiosis, since surface-spread pachytene chromosomes are several times the length of metaphase chromosomes and the decondensed chromatin loops are attached to the lateral elements of the SC. We have applied this technique to analyze the location and organization of three different repetitive DNA sequences, rDNA, an EcoRI satellite DNA of the Sparidae family and telomere DNA in the gilthead seabream Sparus aurata. Our observations indicate that, depending on the type of sequence, the chromatin has different properties with regard to anchorage to the SC.

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.

Evolution of centromeric satellite DNA and its use in phylogenetic studies of the Sparidae family (Pisces, Perciformes).

In this paper, we use the EcoRI centromeric satellite DNA family conserved in Sparidae as a taxonomic and a phylogenetic marker. The analyses of 56 monomeric units (187 bp in size) obtained by means of cloning and PCR from 10 sparid species indicate that this repetitive DNA evolves by concerted evolution. Different phylogenetic inference methods, such as neighbor-joining and UPGMA, group the 56 repeats by taxonomic affinity and support the existence of at least two monophyletic groups within the Sparidae family. These results reinforce the recent taxonomic revision of the genera Sparus and Pagrus and contradict previous classifications of the Sparidae family.

A satellite DNA of the Sparidae family (pisces, perciformes) associated with telomeric sequences.

This paper reports on the isolation and localization of the subtelomeric DraI satellite DNA in the Sparidae family. Gene cloning determined that the DraI satellite DNA is present in only 3 species (Pagrus pagrus, P. auriga, and Pagellus erythrinus) of the 10 Sparidae species analyzed. The results were confirmed by PCR amplification. This satellite DNA is located in a subtelomeric position in all 48 acrocentric chromosomes of these species. However, interstitial loci are also observed. Sequence analysis of monomers of this repetitive family indicates that the satellite DNA is associated with telomeric sequences, (TTAGGG)n, in at least one species, P. erythrinus. This is the first direct demonstration of the existence of the consensus telomere sequences of vertebrates in fish. Likewise, this report also demonstrates that the ends of fish chromosomes have a structure similar to those of most eukaryote chromosomes, viz., telomere sequences and subtelomeric sequences associated by a boundary in which both types of sequences are interspersed. The recent origin of the DraI satellite DNA and its use as a phylogenetic marker is discussed.

The EcoRI centromeric satellite DNA of the Sparidae family (Pisces, Perciformes) contains a sequence motive common to other vertebrate centromeric satellite DNAs.

By means of cloning, sequencing, and fluorescence in situ hybridization, we have determined that the EcoRI satellite DNA family is conserved in the 10 sparid species analyzed here. Its conservation, its chromosomal location at the centromere of each chromosome, and its structural features could make this satellite DNA family an important structural and/or functional element of the centromeres of these species. Monomeric units of this satellite DNA have a consensus length of 187 bp. Its sequence is characterized by a high AT content and the presence of short runs of consecutive AT base pairs. These monomeric EcoRI repeats also contain three to four copies, depending on the species, of a short sequence reflecting the repetitive duplication and subsequent divergence of an ancestral 9-bp sequence in this family. This sequence motive is conserved in some parts of the monomeric units of the different species studied at the same positions, and, precisely, surrounding the area in which the curvature of the monomeric molecule is greatest. The 9-bp sequence motive is similar to other direct-repeat sequences of the centromeric satellite DNAs of other vertebrates, including those of amphibians and mammals.

Cytogenetic analysis of gilthead seabream Sparus aurata (Pisces, Perciformes), a deletion affecting the NOR in a hatchery stock.

We have cytogenetically characterized a hatchery stock of gilthead seabream, Sparus aurata. The study included larvae, juveniles and adults. In S. aurata (diploid chromosome number 2n = 48), a pair of NORs is located at the ends of the short arms of the first submetacentric pair of chromosomes. In this stock we discovered a polymorphism which affects the NORs, and, by means of several cytogenetic and molecular techniques, we demonstrate that this polymorphism is due to the complete deletion of one of the two NORs in a high number of individuals. The significance of these cytogenetic characteristics for this species are discussed since they may be the source of aquaculture problems.

Cloning and characterization of a fish centromeric satellite DNA.

A highly repetitive DNA sequence family from the genome of Sparus aurata has been cloned and characterized. The family is composed of repeat units of 186 bp in length, and it accounts for 2% of the fish genome. Data from Southern blots and in situ hybridization demonstrate that repeating units are tandemly arranged at the centromeres of all the chromosomes in this species. The repetitive sequence is AT rich (67%) and is characterized by short stretches of consecutive AT base pairs and by short direct and inverted repeats. Sequence analysis of six cloned monomers of the family reveals some variation among clones at random positions and also distinguishes two subfamilies of repeats that differ in a highly divergent block of 31 bp. These two subfamilies do not seem to be located in separate domains but occur together in the centromere of each chromosome pair. The presence of this repeat family in the genome of other Sparidae species, some of which are relatively distant from S. aurata, indicates that this repetitive sequence could be an important component of the centromere in this fish family.