Isolation and characterization of two families of satellite DNA with repetitive units of 135 bp and 2.5 kb in the ant Monomorium subopacum (Hymenoptera, Formicidae)

Analyzing the satellite DNA in the ant species Monomorium subopacum we found two unrelated families of satellite DNA. Because these satellite DNA families were isolated using the two enzymes HaeIII and EcoRI we called the two families HaeIII and EcoRI family, respectively. The HaeIII family proved to be organized in a 135-bp basic unit repeat, the EcoRI family in a 2.5-kb basic unit repeat. The latter represents perhaps the longest satellite DNA isolated up to now in insects. The HaeIII family apparently comprises about 10% of the total genomic DNA whereas the EcoRI family represents only about 1-2%. A comparative analysis of the two satellite DNA sequences showed no homology between the two families although both sequences possessed long A and T stretches. Eight of the 34 chromosomes showed hybridization with the HaeIII family and hybridization signals are visible in six chromosomes with the EcoRI family. Analysis of the electrophoretic mobility of satellite DNA on non-denaturing polyacrylamide showed that the HaeIII family is only slightly curved. However, the unit of the EcoRI satellite DNA family has curvature, especially the first 1000 bp of the monomeric repeat, in which this DNA is AT rich and has numerous A and T stretches. There are also internal inverted subrepeats in each family. The sequences of satellite DNA families found in Monomorium subopacum are different from the sequences of other satellite DNAs cloned in insects, including other species of ants.     

Boom-Bust Turnovers of Megabase-Sized Centromeric DNA in Solanum Species: Rapid Evolution of DNA Sequences Associated with Centromeres

Centromeres are composed of long arrays of satellite repeats in most multicellular eukaryotes investigated to date. The satellite repeat–based centromeres are believed to have evolved from “neocentromeres” that originally contained only single- or low-copy sequences. However, the emergence and evolution of the satellite repeats in centromeres has been elusive. Potato (Solanum tuberosum) provides a model system for studying centromere evolution because each of its 12 centromeres contains distinct DNA sequences, allowing comparative analysis of homoeologous centromeres from related species. We conducted genome-wide analysis of the centromeric sequences in Solanum verrucosum, a wild species closely related to potato. Unambiguous homoeologous centromeric sequences were detected in only a single centromere (Cen9) between the two species. Four centromeres (Cen2, Cen4, Cen7, and Cen10) in S. verrucosum contained distinct satellite repeats that were amplified from retrotransposon-related sequences. Strikingly, the same four centromeres in potato contain either different satellite repeats (Cen2 and Cen7) or exclusively single- and low-copy sequences (Cen4 and Cen10). Our sequence comparison of five homoeologous centromeres in two Solanum species reveals rapid divergence of centromeric sequences among closely related species. We propose that centromeric satellite repeats undergo boom-bust cycles before a favorable repeat is fixed in the population.     

Higher-Order Organization of Subrepeats and the Evolution of Cervid Satellite I DNA

Based on sequence analyses of 17 complete centromeric DNA monomers from ten different deer species, a model is proposed for the genesis, evolution, and genomic organization of cervid satellite I DNA. All cervid satellite I DNA arose from the initial amplification of a 31-bp DNA sequence. These 31-bp subrepeats were organized in a hierarchical fashion as 0.8-kb monomers in plesiometacarpalia deer and 1-kb monomers in telemetacarpalia deer. The higher-order repeat nature of cervid centromeric satellite DNA monomers accounts for their high intragenomic and intraspecific sequence conservation. Such high intraspecific sequence conservation validates the use of a single cervid satellite I DNA monomer from each deer species for interspecific sequence comparisons to elucidate phylogenetic relationships. Also, a specific 0.18-kb tandem duplication was observed in all 1-kb monomers, implying that 1-kb cervid satellite I DNA monomers arose from an unequal crossover event between two similar 0.8-kb ancestral DNA sequences. Received: 28 May 1996 / Accepted: 24 October 1996     

Isolation of a variant family of mouse minor satellite DNA that hybridizes preferentially to chromosome 4

Two cosmids (HRS-1 and HRS-2) containing mouse minor satellite DNA sequences have been isolated from a mouse genomic library. In situ hybridization under moderate stringency conditions to metaphase chromosomes from RCS-5, a tumor cell line derived from the SJL strain, mapped both HRS-1 and HRS-2 to the centromeric region of chromosome 4. Sequence data indicate that these cloned minor satellite DNA sequences have a basic higher order repeat of 180 bp, composed of three diverged 60-bp monomers. Digestion of mouse genomic DNA with several restriction enzymes produces a ladder of minor satellite fragments based on a 120-bp repeat. The restriction enzyme NlaIII (CATG) digests all the minor satellite DNA into three prominent bands of 120, 240, and 360 bp and a weak band of 180 bp. Thus, the majority of minor satellite sequences in the genome are arranged in repeats based on a 120-bp dimer, while the family of minor satellite sequences described here represents a rare variant of these sequences. Our results raise the possibility that there may be other variant families of minor satellites analogous to those of alphoid DNA present in humans.     

Molecular cytogenetics of the equidae. II. purification and cytological localization of a (G + C)-rich satellite DNA from Equus hemionus onager and cross-species hybridization to E. asinus chromosomes

A (G + C)-rich satellite DNA component (p = 1.716 g/ml) has been fractionated from the total DNA of the Iranian subspecies of the Asiatic wild ass, Equus hemionus onager, by successive dactinomycin-CsCl and netropsin sulfate-CsCl isopycnic gradients. Complementary 3H-RNA (cRNA) transcribed from the satellite DNA hybridized predominantly to the centromeric and telomeric constitutive heterochromatic regions of onager chromosomes. These studies have suggested that satellite DNA's with similar sequences are present in the centromeric, as well as telomeric, heterochromatic regions of some onager chromosomes. The centromeric region of the fusion metacentric t(23;24) of the onager is deficient in sequences homologous to the onager 1.716 g/ml satellite DNA, indicating a loss of satellite DNA during fusion or an amplification of the satellite DNA in the centromeric regions of the acrocentric chromosomes 23 and 24 subsequent to fission. Sequences complementary to onager 1.716 g/ml satellite DNA show extensive hybridization to the constitutive heterochromatin of the feral donkey (E. asinus) karyotype, consistent with a view of conservation and amplification of similar or identical sequences in the two species.     

Isolation and characterization of salmonid telomeric and centromeric satellite DNA sequences

Satellite DNA clones with a 37 bp repeat unit were obtained from BglII-digested genomic DNA of Masu salmon (Oncorhynchus masou) and Chum salmon (O. keta). Fluorescence in situ hybridization (FISH) analysis with the isolated clones as a probe showed that these repetitive sequences were localized in the telomeric regions of chromosomes in both species. Southern and dot blot analyses suggested conservation of homologous sequences with similar repeat unit in other salmonids including the species of the genus Oncorhynchus and Salvelinus, but lack or scarcity of such sequences in the genus Hucho and Salmo. Similarly, polymerase chain reaction (PCR)-based cloning of satellite DNA referring to a reported Rainbow trout (O. mykiss) centromeric sequence was successful for the Oncorhynchus, Salvelinus and Hucho species. The obtained satellite DNA clones were localized with FISH in the centromeric regions of chromosomes of the species from these three genera. Although PCR cloning of the centromeric satellite DNA had failed in the Salmo species due to some base changes in the priming sites, dot blot hybridization analysis suggested conservation of homologous satellite DNA in the genus Salmo as in the other three genera. In the neighbor-joining tree of cloned centromeric satellite DNA sequences, the genus Oncorhynchus and Salvelinus formed adjacent clades, and the clade of the genus Hucho included the reported centromeric sequence of the genus Salmo. Conservation pattern and molecular phylogeny of the telomeric and centromeric satellite DNA sequences isolated herein support a close phylogenetic relationship between the genus Oncorhynchus and Salvelinus and between the Salmo and Hucho.     

Structure and genomic organization of centromeric repeats in<Emphasis Type="Italic"> Arabidopsis</Emphasis> species

Centromeric repetitive sequences were isolated from Arabidopsis halleri ssp. gemmifera and A. lyrata ssp. kawasakiana. Two novel repeat families isolated from A. gemmifera were designated pAge1 and pAge2. These repeats are 180 bp in length and are organized in a head-to-tail manner. They are similar to the pAL1 repeats of A. thaliana and the pAa units of A. arenosa. Both A. gemmifera and A. kawasakiana possess the pAa, pAge1 and pAge2 repeat families. Sequence comparisons of different centromeric repeats revealed that these families share a highly conserved region of approximately 50 bp. Within each of the four repeat families, two or three regions showed low levels of sequence variation. The average difference in nucleotide sequence was approximately 10% within families and 30% between families, which resulted in clear distinctions between families upon phylogenetic analysis. FISH analysis revealed that the localization patterns for the pAa, pAge1 and pAge2 families were chromosome specific in A. gemmifera and A. kawasakiana. In one pair of chromosomes in A. gemmifera, and three pairs of chromosomes in A. kawasakiana, two repeat families were present. The presence of three families of centromeric repeats in A. gemmifera and A. kawasakiana indicates that the first step toward homogenization of centromeric repeats occurred at the chromosome level.Communicated by W. R. McCombie     

Patterns of DNA Variation Among Three Centromere Satellite Families in <Emphasis Type="Italic">Arabidopsis halleri</Emphasis> and <Emphasis Type="Italic">A</Emphasis>. <Emphasis Type="Italic">lyrata</Emphasis>

We describe patterns of DNA variation among the three centromeric satellite families in Arabidopsis halleri and lyrata. The newly studied subspecies (A. halleri ssp. halleri and A. lyrata ssp. lyrata and petraea), like the previously studied A. halleri ssp. gemmifera and A. lyrata ssp. kawasakiana, have three different centromeric satellite families, the older pAa family (also present in A. arenosa) and two families, pAge1 and pAge2, that probably evolved more recently. Sequence variability is high in all three satellite families, and the pAa sequences do not cluster by their species of origin. Diversity in the pAge2 family is complex, and different from variation among copies of the other two families, showing clear evidence for exchange events among family members, especially in A. halleri ssp. halleri. In A. lyrata ssp. lyrata there is some evidence for recent rapid spread of pAge2 variants, suggesting selection favoring these sequences. Electronic Supplementary Material Electronic Supplementary material is available for this article at and accessible for authorised users. [Reviewing Editor: Dr. Brian Morton]     

Duplication of centromeric histone H3 (HTR12) gene in Arabidopsis halleri and A. lyrata, plant species with multiple centromeric satellite sequences

Arabidopsis halleri and lyrata have three different major centromeric satellite sequences, a unique finding for a diploid Arabidopsis species. Since centromeric histones coevolve with centromeric satellites, these proteins would be predicted to show signs of selection when new centromere satellites have recently arisen. We isolated centromeric protein genes from A. halleri and lyrata and found that one of them, HTR12 (CENP-A), is duplicated, while CENP-C is not. Phylogenetic analysis indicates that the HTR12 duplication occurred after these species diverged from A. thaliana. Genetic mapping shows that HTR12 copy B has the same genomic location as the A. thaliana gene; the other copy (A, at the other end of the same chromosome) is probably the new copy. To test for selection since the duplication, we surveyed diversity at both HTR12 loci within A. lyrata. Overall, there is no strong evidence for an "evolutionary arms race" causing multiple replacement substitutions. The A. lyrata HTR12B sequences fall into three classes of haplotypes, apparently maintained for a long time, but they all encode the same amino acid sequence. In contrast, HTR12A has low diversity, but many variants are amino acid replacements, possibly due to independent selective sweeps within populations of the species.     

Structure of DNA near long tandem arrays of alpha satellite DNA at the centromere of human chromosome 7.

The centromeric regions of human chromosomes contain long tracts of tandemly repeated DNA, of which the most extensively characterized is alpha satellite. In a screen for additional centromeric DNA sequences, four phage clones were obtained which contain alpha satellite as well as other sequences not usually found associated with tandemly repeated alpha satellite DNA, including L1 repetitive elements, an Alu element, and a novel AT-rich repeated sequence. The alpha satellite DNA contained within these clones does not demonstrate the higher-order repeat structure typical of tandemly repeated alpha satellite. Two of the clones contain inversions; instead of the usual head-to-tail arrangement of alpha satellite monomers, the direction of the monomers changes partway through each clone. The presence of both inversions was confirmed in human genomic DNA by polymerase chain reaction amplification of the inverted regions. One phage clone contains a junction between alpha satellite DNA and a novel low-copy repeated sequence. The junction between the two types of DNA is abrupt and the junction sequence is characterized by the presence of runs of A's and T's, yielding an overall base composition of 65% AT with local areas > 80% AT. The AT-rich sequence is found in multiple copies on chromosome 7 and homologous sequences are found in (peri)centromeric locations on other human chromosomes, including chromosomes 1, 2, and 16. As such, the AT-rich sequence adjacent to alpha satellite DNA provides a tool for the further study of the DNA from this region of the chromosome. The phage clones examined are located within the same 3.3-Mb SstII restriction fragment on chromosome 7 as the two previously described alpha satellite arrays, D7Z1 and D7Z2. These new clones demonstrate that centromeric repetitive DNA, at least on chromosome 7, may be more heterogeneous in composition and organization than had previously been thought.     

Whole-genome fractionation rapidly purifies DNA from centromeric regions

The condensed centromeric regions of higher eukaryotic chromosomes contain satellite sequences, transposons and retroelements, as well as transcribed genes that perform a variety of functions. These chromosomal domains nucleate kinetochores, mediate sister chromatid cohesion and inhibit recombination, yet their characterization has often lagged behind that of chromosome arms. Here, we describe a whole-genome fractionation technique that rapidly identifies bacterial artificial chromosome (BAC) clones derived from plant centromeric regions. This approach, which relies on hybridization of methylated genomic DNA, revealed BACs that correspond to the genetically mapped and sequenced Arabidopsis thaliana centromeric regions. Extending this method to other species in the Brassicaceae family identified centromere-linked clones and provided genome-wide estimates of methylated DNA abundance. Sequencing these clones will elucidate the changes that occur during plant centromere evolution. This genomic fractionation technique could identify centromeric DNA in genomes with similar methylation and repetitive DNA content, including those from crops and mammals.     

植物着丝粒结构和功能的研究进展

着丝粒是真核生物有丝分裂和减数分裂染色体正确分离和传递所必需的染色体区域。十多年来, 已对包括拟南芥、水稻、玉米在内的一些植物的着丝粒进行了较深入的分子生物学研究。在不同的植物间, 着丝粒DNA的保守性很低, 呈现快速进化, 但着丝粒的DNA序列类型和组织方式基本相似, 一般是由夹杂排列着的卫星DNA串联重复阵列和着丝粒专一的反转录转座子构成。与着丝粒DNA相反, 着丝粒/着丝点的结构性和瞬时蛋白质在包括植物在内的真核生物中保守。与其他真核生物的情况一样, 拥有含着丝粒组蛋白H3(CENH3)的核小体是植物功能着丝粒染色质最基本的特征, CENH3在着丝粒染色质的识别和保持中起着关键作用。     

Genomic organization of alpha satellite DNA on human chromosome 7: evidence for two distinct alphoid domains on a single chromosome.

A complete understanding of chromosomal disjunction during mitosis and meiosis in complex genomes such as the human genome awaits detailed characterization of both the molecular structure and genetic behavior of the centromeric regions of chromosomes. Such analyses in turn require knowledge of the organization and nature of DNA sequences associated with centromeres. The most prominent class of centromeric DNA sequences in the human genome is the alpha satellite family of tandemly repeated DNA, which is organized as distinct chromosomal subsets. Each subset is characterized by a particular multimeric higher-order repeat unit consisting of tandemly reiterated, diverged alpha satellite monomers of approximately 171 base pairs. The higher-order repeat units are themselves tandemly reiterated and represent the most recently amplified or fixed alphoid sequences. We present evidence that there are at least two independent domains of alpha satellite DNA on chromosome 7, each characterized by their own distinct higher-order repeat structure. We determined the complete nucleotide sequences of a 6-monomer higher-order repeat unit, which is present in approximately 500 copies per chromosome 7, as well as those of a less-abundant (approximately 10 copies) 16-monomer higher-order repeat unit. Sequence analysis indicated that these repeats are evolutionarily distinct. Genomic hybridization experiments established that each is maintained in relatively homogeneous tandem arrays with no detectable interspersion. We propose mechanisms by which multiple unrelated higher-order repeat domains may be formed and maintained within a single chromosomal subset.     

A new family of satellite DNA sequences as a major component of centromeric heterochromatin in owls (Strigiformes)

We isolated a new family of satellite DNA sequences from Hae III- and Eco RI-digested genomic DNA of the Blakistons fish owl ( Ketupa blakistoni). The repetitive sequences were organized in tandem arrays of the 174 bp element, and localized to the centromeric regions of all macrochromosomes, including the Z and W chromosomes, and microchromosomes. This hybridization pattern was consistent with the distribution of C-band-positive centromeric heterochromatin, and the satellite DNA sequences occupied 10% of the total genome as a major component of centromeric heterochromatin. The sequences were homogenized between macro- and microchromosomes in this species, and therefore intraspecific divergence of the nucleotide sequences was low. The 174 bp element cross-hybridized to the genomic DNA of six other Strigidae species, but not to that of the Tytonidae, suggesting that the satellite DNA sequences are conserved in the same family but fairly divergent between the different families in the Strigiformes. Secondly, the centromeric satellite DNAs were cloned from eight Strigidae species, and the nucleotide sequences of 41 monomer fragments were compared within and between species. Molecular phylogenetic relationships of the nucleotide sequences were highly correlated with both the taxonomy based on morphological traits and the phylogenetic tree constructed by DNA-DNA hybridization. These results suggest that the satellite DNA sequence has evolved by concerted evolution in the Strigidae and that it is a good taxonomic and phylogenetic marker to examine genetic diversity between Strigiformes species.An erratum to this article can be found at Communicated by Y. Hiraoka     

Segmental amplification in a satellite DNA: Restriction enzyme analysis of the major satellite ofMacropus rufogriseus

The 1.708 g/cc satellite DNA of the red necked wallaby is shown to consist of a number of related families of sequences arranged in tandem arrays. Particular families are subpopulations of other families; their distribution supports a model of successive amplification events during the generation of the satellite. In each amplification episode one 2,500 bp unit is multiplied into a tandemly repeated array of that unit (segmental amplification). The 1.708 g/cc sequences can be detected in related kangaroo species in much reduced amount, and with changes to the long order periodicity of the repeat units.     

Chromatin immunoprecipitation reveals that the 180-bp satellite repeat is the key functional DNA element of Arabidopsis thaliana centromeres

The centromeres of Arabidopsis thaliana chromosomes contain megabases of complex DNA consisting of numerous types of repetitive DNA elements. We developed a chromatin immunoprecipitation (ChIP) technique using an antibody against the centromeric H3 histone, HTR12, in Arabidopsis. ChIP assays showed that the 180-bp centromeric satellite repeat was precipitated with the antibody, suggesting that this repeat is the key component of the centromere/kinetochore complex in Arabidopsis.     

The organization of the mouse satellite DNA at centromeres

The mouse genome contains a major and a minor satellite DNA family of repetitive DNA sequences. The use of 5-azacytidine has allowed us to demonstrate that these satellite DNAs are organized in two separate domains at the centromeres of mouse chromosomes. The minor satellite is closer to the short arms of the acrocentric chromosomes than the major satellite. The major satellite is farther away, flanking the minor satellite and adjacent to the euchromatic long arm of each mouse chromosome. At the level of resolution afforded by the in situ hybridization technique it would appear that the organization of the centromeric domain of the mouse is similar to that in man. That is, both contain two repetitive DNA sequence families arranged in major blocks.     

Meiotic chromosome behaviour reflects levels of sequence divergence inSus scrofa domestica satellite DNA

We present a general model for the evolution of chromosome-specific satellite DNA subfamilies.Sus scrofa domestica has a bimodal karyotype with two autosomal subsets of 12 meta-/submetacentric (Mc) and 6 acrocentric (Ac) chromosome types (Mc and Ac subgenomes). We show that the centromeric heterochromatin is characterised by two distinct satellite DNA families designed Mc1 and Ac2. Mc1 is a diverse satellite family of the Mc subgenome of which certain members with a 100 bp repeat unit are found to occur at the pericentromeric regions of each Mc autosome, while others are chromosome-specific, e.g. clone Mc pAv1.5, a higher order repeat variant, which hybridises specifically to chromosome 1. Ac2 is a homogeneous satellite occurring at the subterminal pericentromeric regions of all Ac autosomes. DNA sequence analyses showed that all clones investigated are built up from a 14 bp repeat unit which is highly conserved. In situ hybridisation to meiotic pachytene nuclei revealed a distinct spatial arrangement of the Ac2 centromeric satellite.     

Molecular analysis of holocentric centromeres of Luzula species

Luzula spp, like the rest of the members of the Juncaceae family, have holocentric chromosomes. Using the rice 155-bp centromeric tandem repeat sequence (RCS2) as a probe, we have isolated and characterized a 178-bp tandem sequence repeat (LCS1) from Luzula nivea. The LCS1 sequence is present in all Luzula species tested so far (except L. pilosa) and like other satellite repeats found in heterochromatin, the cytosine residues are methylated within the LCS1 repeats. Using fluorescent in situ hybridization (FISH) experiments we have shown that there are at least 5 large clusters of LCS1 sequences distributed at heterochromatin regions along each of the 12 chromosomes of L. nivea. We have shown that a centromeric antibody Skp1 co-localizes with these heterochromatin regions and with the LCS1 sequences. This suggests that the LCS1 sequences are part of regions which function as centromeres on these holocentric chromosomes. Furthermore, using the BrdU assay to identify replication sites, we have shown that these heterochromatin sites containing LCS1 associate when being replicated in root interphase nuclei. Our results also show premeiotic chromosome association during anther development as indicated by single-copy BAC in situ and the presence of fewer LCS1 containing heterochromatin sites in these cells.     

The formation and evolution of centromeric satellite repeats in Saccharum species

Centromeres in eukaryotes are composed of tandem DNAs and retrotransposons. However, centromeric repeats exhibit considerable diversity, even among closely related species, and their origin and evolution are largely unknown. We conducted a genome-wide characterization of the centromeric sequences in sugarcane (Saccharum officinarum). Four centromeric tandem repeat sequences, So1, So103, So137 and So119, were isolated. So1 has a monomeric length of 137 bp, typical of a centromeric satellite, and has evolved four variants. However, these So1 variants had distinct centromere distributions and some were unique to an individual centromere. The distributions of the So1 variants were unexpectedly consistent among the Saccharum species that had different basic chromosome numbers or ploidy levels, thus suggesting evolutionary stability for approximately 7 million years in sugarcane. So103, So137 and So119 had unusually longer monomeric lengths that ranged from 327 to 1371 bp and lacked translational phasing on the CENH3 nucleosomes. Moreover, So103, So137 and So119 seemed to be highly similar to retrotransposons, which suggests that they originated from these mobile elements. Notably, all three repeats were flanked by direct repeats, and formed extrachromosomal circular DNAs (eccDNAs). The presence of circular molecules for these retrotransposon-derived centromeric satellites suggests an eccDNA-mediated centromeric satellite formation pathway in sugarcane.