Colocalization of repetitive DNAs and silencing of major rRNA genes. A case report of the fish Astyanax janeiroensis

The heterochromatin composition and loca- tion in the genome of the fish Astyanax janeiroensis was investigated using Chromomycin A(3) and DAPI fluorochromes and fluorescence in situ hybridization (FISH) with 18S rDNA and As51 satellite DNA probes, respectively. Distinct repetitive DNA classes were found, namely: (1) C-positive centromeric/telomeric heterochromatin, (2) NOR-associated GC-rich heterochromatin (18S(+)/GC(+)) and (3) As51(+)/18S(+) heterochromatin colocalized on 14 distinct heterochromatic domains with attenuated fluorescence of DAPI staining (As51(+)/18S(+)/DAPI attenuated signal). Besides these fourteen associated repetitive DNAs, another eight sites with only 18S rDNA were also found, comprising altogether 22 18S rDNA sites in the genome of the species under study. Up to seven 18S rDNA sites were found to be active, i.e., were characterized as positive after silver staining (Ag-NORs). It was noteworthy that in all As51(+)/18S(+) domains the 18S rDNA were not found to be active sites due to the silencing of these genes when associated with the As51 satellite DNA in the same heterochromatic domain. The dispersion of the As51 sites in the genome of the species is hypothesized to probably originate from a transposable element. Several chromosomal and karyotype markers are similar between A. janeiroensis and A. scabripinnis, indicating a close relationship between these species.     

Satellite DNA and chromosomes in Neotropical fishes: methods,applications and perspectives

Constitutive heterochromatin represents a substantial portion of the eukaryote genome, and it is mainly composed of tandemly repeated DNA sequences, such as satellite DNAs, which are also enriched by other dispersed repeated elements, including transposons. Studies on the organization, structure, composition and in situ localization of satellite DNAs have led to consistent advances in the understanding of the genome evolution of species, with a particular focus on heterochromatic domains, the diversification of heteromorphic sex chromosomes and the origin and maintenance of B chromosomes. Satellite DNAs can be chromosome specific or species specific, or they can characterize different species from a genus, family or even representatives of a given order. In some cases, the presence of these repeated elements in members of a single clade has enabled inferences of a phylogenetic nature. Genomic DNA restriction, using specific enzymes, is the most frequently used method for isolating satellite DNAs. Recent methods such as C₀t–1 DNA and chromosome microdissection, however, have proven to be efficient alternatives for the study of this class of DNA. Neotropical ichthyofauna is extremely rich and diverse enabling multiple approaches with regard to the differentiation and evolution of the genome. Genome components of some species and genera have been isolated, mapped and correlated with possible functions and structures of the chromosomes. The 5SHindIII‐DNA satellite DNA, which is specific to Hoplias malabaricus of the Erythrinidae family, has an exclusively centromeric location. The As51 satellite DNA, which is closely correlated with the genome diversification of some species from the genus Astyanax, has also been used to infer relationships between species. In the Prochilodontidae family, two repetitive DNA sequences were mapped on the chromosomes, and the SATH 1 satellite DNA is associated with the origin of heterochromatic B chromosomes in Prochilodus lineatus. Among species of the genus Characidium and the Parodontidae family, amplifications of satellite DNAs have demonstrated that these sequences are related to the differentiation of heteromorphic sex chromosomes. The possible elimination of satellite DNA units could explain the genome compaction that occurs among some species of Neotropical Tetraodontiformes. These topics are discussed in the present review, showing the importance of satellite DNA analysis in the differentiation and karyotype evolution of Actinopterygii.     

Chromosome polymorphism in Astyanax fasciatus (Teleostei, Characidae). 2--Chromosomal location of a satellite DNA

Studies about composition of repetitive sequences and their chromosomal location have been helpful to evolutionary studies in many distinct organisms. In order to keep on assessing the possible relationships among different cytotypes of Astyanax fasciatus (Teleostei, Characiformes) in the Mogi-Gua?u River (S?o Paulo State, Brazil), C-banding, chromomycin A(3) staining, and fluorescent in situ hybridization with a repetitive DNA sequence (As51) isolated from Astyanax scabripinnis were performed in the present work. The constitutive heterochromatin was distributed in terminal regions on long arms of submetacentric, subtelocentric, and acrocentric chromosomes and in the terminal region on short arms of a pair of submetacentric chromosomes in both standard cytotypes. This latter heterochromatic site was also GC-rich, as revealed by chromomycin A(3) staining, corresponding to the nucleolar organizer region (NOR), as shown by previous studies. The sites of the satellite As51 DNA were located in terminal regions on long arms of several chromosomes. Some variant karyotypic forms, which diverge from the two standard cytotypes, also presented distinctive chromosomes carrying As51 satellite DNA. It is possible that the standard 2n = 46 cytotype represents an invader population in the Mogi-Gua?u River able to interbreed with the resident standard 2n = 48 cytotype. Therefore, the variant karyotypes would be related to a possible viable offspring, where complementary chromosomal rearrangements could favor new locations of the satellite DNA analyzed.     

The population biology of transposable elements

A transposable element can be defined as a DNA sequence capable of moving to new sites in the genome. Such DNA sequences have been described in a wide range of organisms. The evolutionary processes affecting transposable elements can thus be divided into two categories: changes in sequence and changes in genomic location. As with other types of evolutionary change, the nature of the evolutionary process will be reflected in the extent and type of genetic variation existing in wild populations. Quantitative models of the evolution of transposable element sequences and positions will be outlined, and related to relevant data. The extent to which models designed to describe obvious transposable elements such as the mobile sequences of Drosophila are also applicable to interspersed repetitive DNAs from other species will be discussed.     

Chromosomal organization of repetitive DNA sequences in Astyanax bockmanni (Teleostei, Characiformes): dispersive location, association and co-localization in the genome

Repetitive DNA sequences constitute a great portion of the genome of eukaryotes and are considered key components to comprehend evolutionary mechanisms and karyotypic differentiation. Aiming to contribute to the knowledge of chromosome structure and organization of some repetitive DNA classes in the fish genome, chromosomes of two allopatric populations of Astyanax bockmanni were analyzed using classic cytogenetics techniques and fluorescent in situ hybridization, with probes for ribosomal DNA sequences, histone DNA and transposable elements. These Astyanax populations showed the same diploid number (2n = 50), however with differences in chromosome morphology, distribution of constitutive heterochromatin, and location of 18S rDNA and retroelement Rex3 sites. In contrast, sites for 5S rDNA and H1, H3 and H4 histones showed to be co-located and highly conserved. Our results indicate that dispersion and variability of 18S rDNA and heterochromatin sites are not associated with macro rearrangements in the chromosome structure of these populations. Similarly, distinct evolutionary mechanisms would act upon histone genes and 5S rDNA, contributing to chromosomal association and co-location of these sequences. Data obtained indicate that distinct mechanisms drive the spreading of repetitive DNAs in the genome of A. bockmanni. Also, mobile elements may account for the polymorphism of the major rDNA sites and heterochromatin in this genus.     

Transposable elements and the evolution of genome size in eukaryotes

It is generally accepted that the wide variation in genome size observed among eukaryotic species is more closely correlated with the amount of repetitive DNA than with the number of coding genes. Major types of repetitive DNA include transposable elements, satellite DNAs, simple sequences and tandem repeats, but reliable estimates of the relative contributions of these various types to total genome size have been hard to obtain. With the advent of genome sequencing, such information is starting to become available, but no firm conclusions can yet be made from the limited data currently available. Here, the ways in which transposable elements contribute both directly and indirectly to genome size variation are explored. Limited evidence is provided to support the existence of an approximately linear relationship between total transposable element DNA and genome size. Copy numbers per family are low and globally constrained in small genomes, but vary widely in large genomes. Thus, the partial release of transposable element copy number constraints appears to be a major characteristic of large genomes.     

Bats with hATs: evidence for recent DNA transposon activity in genus Myotis

Transposable elements make up a significant fraction of many eukaryotic genomes. Although both classes of transposable elements, the DNA transposons and the retrotransposons, show substantial expansion in plants and invertebrates, the DNA transposons are thought to have become inactive in mammalian genomes long ago. Here, we report the first evidence for recent activity of DNA transposons in a mammalian lineage, the bat genus Myotis. Six recently active families of nonautonomous hobo/Activator/TAM transposons were identified in the Myotis lucifugus genome using computational tools. Low sequence divergence among the individual sequences and between individual sequences and their respective consensus sequences suggest their recent expansion in the M. lucifugus genome. Furthermore, amplification and sequencing of polymorphic insertion loci in a related taxon, M. austroriparius, confirms their recent activity. Myotis is one of the largest mammalian genera with 103 species. The discovery of DNA transposon activity in this genus may therefore influence our understanding of genome evolution and diversification in bats and in mammals in general. Furthermore, the identification of a likely autonomous element may lead to new approaches for mammalian genetic manipulation.     

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.     

B chromosomes in the fish Astyanax scabripinnis (Characidae, Tetragonopterinae): an overview in natural populations

Astyanax scabripinnis, a small neotropical freshwater fish, is a headwater species living in small tributaries of many Brazilian rivers, where they form isolated populations. This species harbors a B chromosome system in several populations. Among the several kinds of Bs reported in this species, the B(M) variant, a large metacentric of a similar size to the largest A chromosome, is the most widespread in natural populations. It probably corresponds to the ancestral B type in this species and a very similar B chromosome is also found in other Astyanax species. Strong evidence suggests that this B is an isochromosome showing structural and functional homology between its two arms, as shown by satellite DNA localization and the formation of a ring B univalent during meiosis. The B(SM) and B(m) variants, a large submetacentric and a small metacentric, respectively, represent rare variants and may be derived from structural rearrangements of the B(M) chromosome. In addition, B microchromosomes (B(micro)) were found in some populations. Frequency analyses in mountain populations have shown that B chromosomes are found in populations located at high altitude, but are absent in populations at low altitude, which is consistent with their parasitic nature, given the ecological peculiarities of both kinds of populations.     

Construction of a small Mus musculus repetitive DNA library: identification of a new satellite sequence in Mus musculus.

We report the construction of a small library of recombinant plasmids containing Mus musculus repetitive DNA inserts. The repetitive cloned fraction was derived from denatured genomic DNA by reassociation to a Cot value at which repetitive, but not unique, sequences have reannealed followed by exhaustive S1 nuclease treatment to degrade single stranded DNA. Initial characterizations of this library by colony filter hybridizations have led to the identification of a previously undetected M. musculus minor satellite as well as to clones containing M. musculus major satellite sequences. This new satellite is repeated 10-20 times less than the major satellite in the M. musculus genome. It has a repeat length of 130 nucleotides compared with the M. musculus major satellite with a repeat length of 234 nucleotides. Sequence analysis of the minor satellite has shown that it has a 29 base pair region with extensive homology to one of the major satellite repeating subunits. We also show by in situ hybridization that this minor satellite sequence is located at the centromeres and possibly the arms of at least half the M musculus chromosomes. Sequences related to the minor satellite have been found in the DNA of a related Mus species, Mus spretus, and may represent the major satellite of that species.     

Recent amplification of the kangaroo endogenous retrovirus, KERV, limited to the centromere

Mammalian retrotransposons, transposable elements that are processed through an RNA intermediate, are categorized as short interspersed elements (SINEs), long interspersed elements (LINEs), and long terminal repeat (LTR) retroelements, which include endogenous retroviruses. The ability of transposable elements to autonomously amplify led to their initial characterization as selfish or junk DNA; however, it is now known that they may acquire specific cellular functions in a genome and are implicated in host defense mechanisms as well as in genome evolution. Interactions between classes of transposable elements may exert a markedly different and potentially more significant effect on a genome than interactions between members of a single class of transposable elements. We examined the genomic structure and evolution of the kangaroo endogenous retrovirus (KERV) in the marsupial genus Macropus. The complete proviral structure of the kangaroo endogenous retrovirus, phylogenetic relationship among relative retroviruses, and expression of this virus in both Macropus rufogriseus and M. eugenii are presented for the first time. In addition, we show the relative copy number and distribution of the kangaroo endogenous retrovirus in the Macropus genus. Our data indicate that amplification of the kangaroo endogenous retrovirus occurred in a lineage-specific fashion, is restricted to the centromeres, and is not correlated with LINE depletion. Finally, analysis of KERV long terminal repeat sequences using massively parallel sequencing indicates that the recent amplification in M. rufogriseus is likely due to duplications and concerted evolution rather than a high number of independent insertion events.     

An abundant family of methylated repetitive sequences dominates the genome of Physarum polycephalum.

A significant portion (20%) of the Physarum genome can be isolated as a HpaII-resistant, methylated fraction. Cloned DNA probes containing highly-repeated sequences derived from this fraction were used to define the pattern of structural organisation of homologous repeats in Physarum genomic DNA. It is shown that the probes detect an abundant, methylated family of sequences with an estimated genomic repetition frequency greater than 2100, derived from a large repeated element whose length exceeds 5.8kb. Sequences comprising the long repetitive element dominate the HpaII-resistant compartment and account for between 4-20% of the Physarum genome. Detailed restriction/hybridisation analysis of cloned DNA segments derived from this compartment shows that HpaII/MspI restriction sites within some copies of the long repeated sequence are probably deleted by mutation. Additionally, segments of the repeat are often found in different organisational patterns that represent scrambled versions of its basic structure, and which are presumed to have arisen as a result of recombinational rearrangement in situ in the Physarum genome. Preliminary experiments indicate that the sequences are transcribed and that the structural properties of the repeat bear some resemblance to those of transposable genetic elements defined in other eukaryotic species.     

秦岭羚牛高度重复序列DNA片段的分子克隆和序列分析

羚牛(Budorcas taxicolor)属偶蹄目(Artiodactyla)、牛科(Bovidae),为我国一类大型珍贵保护动物。我们从其基因组中克隆得到若干约800bp的BamHI高度重复序列并对部分克隆进行了序列测定,发现它们显示了很高的同源性。利用其中一个单元为探针,对限制酶消化后的羚牛基因组DNA作杂交分析,发现其杂交谱带不具有个体及亚种间特异性,说明该重复序列在羚牛基因组中具有保守的分布和排列。在牛科动物中,羚牛BamHI片段与绵羊属和山羊属的相关序列具有高度同源性,而与水牛和家牛序列差异较大。这些结果为羚牛与羊亚科物种亲源关系较近的分类学观点提供了分子生物学证据。有证据表明,这些片段可能代表羚牛染色体着丝点的卫星DNA单体。     

秦岭羚牛高度重复序列DNA片段的分子克隆和序列分析

羚牛（Budorcas taxicolor)属偶蹄目（Artiodactyla)、牛科（Bovidae),为我国一类大型珍贵保护动物。我们从其基因组中克隆得到若干约800bp的BamHI高度重复序列并对部分克隆进行了序列测定,发现它们显示了很高的同源性。利用其中一个单元为探针,对限制酶消化后的羚牛基因组DNA作杂交分析,发现其杂交谱带不具有个体及亚种间特异性,说明该重复序列在羚牛基因组中具有保守的分布和排列。在牛科动物中,羚牛BamHI片段与绵羊属和山羊属的相关序列具有高度同源性,而与水牛和家牛序列差异较大。这些结果为羚牛与羊亚科物种亲源关系较近的分类学观点提供了分子生物学证据。有证据表明,这些片段可能代表羚牛染色体着丝点的卫星DNA单体。     

Comparative study of satellite DNA in ants of the Messor genus

The satellite DNA of ants Messor barbarus and Messor bouvieri is analysed. The results are compared with the satellite DNA data from Messor structor previously reported and with new data obtained from the genome of geographically distinct M. structor population, which have shown that this satellite DNA is highly conserved within the species. The satellite DNA is organized as tandemly repeated 79 bp monomers in all species. The sampled sequences of the three species show a high similarity and all belong to the same family of satellite DNA. Sequence comparisons suggested the occurrence of highly effective homogenization mechanism acting upon the ant genomes. In accordance with this hypothesis, putative gene conversion tracts are identified when the different monomers of the same species are compared. The highest sequence conservation in all species corresponds to a single region with inverted repeats. A CENP-B-like motif was found in this region. The possibility that it may be involved in the homogenization of satellite DNA is discussed.     

Classification and molecular organization of satellites elucidated by phylogenetic network analysis - examples from Triturus salamanders and Palorus beetles

A phylogenetic network of 244 satellite DNA sequences across five species of aquatic salamanders (genus Triturus) revealed four types of satellite DNAs in a 'p'-shaped 1-2*-3-4-2* arrangement. Analysis of dimer and trimer DNA sequences revealed a prevalence of homosequential (e.g. 1-1, 2-2) and particular (1-4 and 2-3) heterosequential repeat motifs. Genetic diversity across types and species phylogeny indicated that type 1 and type 4 are derived from types 2 and 3. Support was also found for alternating motifs in Palorus flour beetle tandem repeats. The results were statistically significant, whether or not the underlying satellite DNA phylogenies were robust under bootstrap analysis.     

Concerted evolution,a slow process for ant satellite DNA: study of the satellite DNA in the <Emphasis Type="Italic">Aphaenogaster</Emphasis> genus (Hymenoptera,Formicidae)

A family of satellite DNA is analyzed in seven ant species from the genus Aphaenogaster. This satellite DNA is organized as tandemly repeated sequences with a consensus sequence of 160 bp in length. The sampled sequences show a high similarity and belong to the same family of satellite DNA. However in Aphaenogaster spinosa, two types of repeat clearly differentiated have been found. Phylogenetic analyses using satellite DNA show that sequences do not cluster in a species-specific way, with one exception. Concretely, the second type of repeats of A. spinosa (APSP-II) which constitutes a new satellite DNA subfamily. The obtained results with satellite DNA are compared with those obtained using mitochondrial and nuclear DNA to determine the correlation between evolution of satellite DNA and phylogenetic relationships among the analyzed ants. The high interspecific similarity for the satellite DNA seems not to be in concordance with the concerted evolution pattern, commonly accepted to explain the evolution of satellite DNA. However, the accumulated data suggest that evolution of satellite DNA in ants follows the concerted evolution pattern but that this process is slow in relation with other organisms, probably due to the eusociality and haplodiploidy of these insects.     

A tandemly repetitive centromeric DNA sequence of the fish Hoplias malabaricus (Characiformes: Erythrinidae) is derived from 5S rDNA

A substantial fraction of the eukaryotic genome consists of repetitive DNA sequences that include satellites, minisatellites, microsatellites, and transposable elements. Although extensively studied for the past three decades, the molecular forces that generate, propagate and maintain repetitive DNAs in the genomes are still discussed. To further understand the dynamics and the mechanisms of evolution of repetitive DNAs in vertebrate genome, we searched for repetitive sequences in the genome of the fish species Hoplias malabaricus. A satellite sequence, named 5SHindIII-DNA, which has a conspicuous similarity with 5S rRNA genes and spacers was identified. FISH experiments showed that the 5S rRNA bona fide gene repeats were clustered in the interstitial position of two chromosome pairs of H. malabaricus, while the satellite 5SHindIII-DNA sequences were clustered in the centromeric position in nine chromosome pairs of the species. The presence of the 5SHindIII-DNA sequences in the centromeres of several chromosomes indicates that this satellite family probably escaped from the selective pressure that maintains the structure and organization of the 5S rDNA repeats and become disperse into the genome. Although it is not feasible to explain how this sequence has been maintained in the centromeric regions, it is possible to hypothesize that it may be involved in some structural or functional role of the centromere organization.     

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.     

Repetitive DNA and chromosome evolution in plants

Most higher plant genomes contain a high proportion of repeated sequences. Thus repetitive DNA is a major contributor to plant chromosome structure. The variation in total DNA content between species is due mostly to variation in repeated DNA content. Some repeats of the same family are arranged in tandem arrays, at the sites of heterochromatin. Examples from the Secale genus are described. Arrays of the same sequence are often present at many chromosomal sites. Heterochromatin often contains arrays of several unrelated sequences. The evolution of such arrays in populations is discussed. Other repeats are dispersed at many locations in the chromosomes. Many are likely to be or have evolved from transposable elements. The structures of some plant transposable elements, in particular the sequences of the terminal inverted repeats, are described. Some elements in soybean, antirrhinum and maize have the same inverted terminal repeat sequences. Other elements of maize and wheat share terminal homology with elements from yeast, Drosophila, man and mouse. The evolution of transposable elements in plant populations is discussed. The amplification, deletion and transposition of different repeated DNA sequences and the spread of the mutations in populations produces a turnover of repetitive DNA during evolution. This turnover process and the molecular mechanisms involved are discussed and shown to be responsible for divergence of chromosome structure between species. Turnover of repeated genes also occurs. The molecular processes affecting repeats imply that the older a repetitive DNA family the more likely it is to exist in different forms and in many locations within a species. Examples to support this hypothesis are provided from the Secale genus.