Sequence, Chromatin and Evolution of Satellite DNA

Satellite DNA consists of abundant tandem repeats that play important roles in cellular processes, including chromosome segregation, genome organization and chromosome end protection. Most satellite DNA repeat units are either of nucleosomal length or 5–10 bp long and occupy centromeric, pericentromeric or telomeric regions. Due to high repetitiveness, satellite DNA sequences have largely been absent from genome assemblies. Although few conserved satellite-specific sequence motifs have been identified, DNA curvature, dyad symmetries and inverted repeats are features of various satellite DNAs in several organisms. Satellite DNA sequences are either embedded in highly compact gene-poor heterochromatin or specialized chromatin that is distinct from euchromatin. Nevertheless, some satellite DNAs are transcribed into non-coding RNAs that may play important roles in satellite DNA function. Intriguingly, satellite DNAs are among the most rapidly evolving genomic elements, such that a large fraction is species-specific in most organisms. Here we describe the different classes of satellite DNA sequences, their satellite-specific chromatin features, and how these features may contribute to satellite DNA biology and evolution. We also discuss how the evolution of functional satellite DNA classes may contribute to speciation in plants and animals.

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A species-specific satellite DNA from the entomopathogenic nematode Heterorhabditis indicus

Genome ◽

10.1139/g98-005 ◽

1998 ◽

Vol 41 (2) ◽

pp. 148-153 ◽

Cited By ~ 8

Author(s):

Monique Abadon ◽

Eric Grenier ◽

Christian Laumond ◽

Pierre Abad

Keyword(s):

Dna Sequence ◽

Satellite Dna ◽

Tandem Repeats ◽

Sequence Data ◽

Entomopathogenic Nematode ◽

Consensus Sequence ◽

Repeated Sequence ◽

Nucleotide Sequence Analysis ◽

Specific Sequence ◽

Species Specific

An AluI satellite DNA family has been cloned from the entomopathogenic nematode Heterorhabditis indicus. This repeated sequence appears to be an unusually abundant satellite DNA, since it constitutes about 45% of the H. indicus genome. The consensus sequence is 174 nucleotides long and has an A + T content of 56%, with the presence of direct and inverted repeat clusters. DNA sequence data reveal that monomers are quite homogeneous. Such homogeneity suggests that some mechanism is acting to maintain the homogeneity of this satellite DNA, despite its abundance, or that this repeated sequence could have appeared recently in the genome of H. indicus. Hybridization analysis of genomic DNAs from different Heterorhabditis species shows that this satellite DNA sequence is specific to the H. indicus genome. Considering the species specificity and the high copy number of this AluI satellite DNA sequence, it could provide a rapid and powerful tool for identifying H. indicus strains.Key words: AluI repeated DNA, tandem repeats, species-specific sequence, nucleotide sequence analysis.

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Differentially Amplified Repetitive Sequences Among Aegilops tauschii Subspecies and Genotypes

Frontiers in Plant Science ◽

10.3389/fpls.2021.716750 ◽

2021 ◽

Vol 12 ◽

Author(s):

Rahman Ebrahimzadegan ◽

Fatemeh Orooji ◽

Pengtao Ma ◽

Ghader Mirzaghaderi

Keyword(s):

Dna Sequences ◽

Tandem Repeats ◽

Repetitive Sequences ◽

Aegilops Tauschii ◽

Distribution Patterns ◽

Snp Analysis ◽

Specific Sequence ◽

Factors Affecting ◽

Illumina Sequence ◽

Species Specific

Genomic repetitive sequences commonly show species-specific sequence type, abundance, and distribution patterns, however, their intraspecific characteristics have been poorly described. We quantified the genomic repetitive sequences and performed single nucleotide polymorphism (SNP) analysis between 29 Ae. tauschii genotypes and subspecies using publicly available raw genomic Illumina sequence reads and used fluorescence in situ hybridization (FISH) to experimentally analyze some repeats. The majority of the identified repetitive sequences had similar contents and proportions between anathera, meyeri, and strangulata subspecies. However, two Ty3/gypsy retrotransposons (CL62 and CL87) showed significantly higher abundances, and CL1, CL119, CL213, CL217 tandem repeats, and CL142 retrotransposon (Ty1/copia type) showed significantly lower abundances in subspecies strangulata compared with the subspecies anathera and meyeri. One tandem repeat and 45S ribosomal DNA (45S rDNA) abundances showed a high variation between genotypes but their abundances were not subspecies specific. Phylogenetic analysis using the repeat abundances of the aforementioned clusters placed the strangulata subsp. in a distinct clade but could not discriminate anathera and meyeri. A near complete differentiation of anathera and strangulata subspecies was observed using SNP analysis; however, var. meyeri showed higher genetic diversity. FISH using major tandem repeats couldn’t detect differences between subspecies, although (GAA)10 signal patterns generated two different karyotype groups. Taken together, the different classes of repetitive DNA sequences have differentially accumulated between strangulata and the other two subspecies of Ae. tauschii that is generally in agreement with spike morphology, implying that factors affecting repeatome evolution are variable even among highly closely related lineages.

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PCR-BASED SYNTHESIS OF REPETITIVE SINGLE-STRANDED DNA FOR APPLICATIONS TO NANOBIOTECHNOLOGY

International Journal of Nanoscience ◽

10.1142/s0219581x05003140 ◽

2005 ◽

Vol 04 (03) ◽

pp. 287-294

Author(s):

SIMA S. ZEIN ◽

ALEXANDRE A. VETCHER ◽

STEPHEN D. LEVENE

Keyword(s):

Dna Sequences ◽

Tandem Repeats ◽

Repetitive Sequences ◽

Practical Interest ◽

Telomeric Sequence ◽

Automated Synthesis ◽

Dna Molecules ◽

Specific Sequence ◽

Single Stranded Dna ◽

Pcr Method

Recent data show that assembly of repetitive-sequence, single-stranded DNA molecules (ssDNA) and carbon nanotubes (CNTs) depend on the specific sequence repeat. Therefore, it is of practical interest to assess various methods for generating single-stranded DNA molecules that contain repetitive sequences. Existing automated synthesis procedures for generating long (> 100 nt) ssDNA molecules generate ssDNA products of variable purity and yield. An alternative to automated synthesis is the polymerase chain reaction (PCR), which provides a powerful tool for the amplification of minute amounts of specific DNA sequences. Here we show that a modified asymmetric PCR method allows synthesis of long ssDNAs comprised of tandem repeats of the repetitive vertebrate telomeric sequence (TTAGGG)n, and is also applicable to arbitrary (repetitive or nonrepetitive) DNA. Long, repetitive deoxynucleotides produced by automated synthesis are surprisingly heterogeneous with respect to both length and sequence. Benefits of the method described here are that long, repetitive ssDNA sequences are generated with high sequence fidelity and yield.

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Centromeric Satellite DNAs: Hidden Sequence Variation in the Human Population

Genes ◽

10.3390/genes10050352 ◽

2019 ◽

Vol 10 (5) ◽

pp. 352 ◽

Cited By ~ 28

Author(s):

Karen H. Miga

Keyword(s):

Human Genome ◽

Satellite Dna ◽

Human Population ◽

Sequence Variation ◽

Tandem Repeats ◽

Association Studies ◽

Unmet Need ◽

Satellite Dnas ◽

Dna Variation ◽

Medical Genomics

The central goal of medical genomics is to understand the inherited basis of sequence variation that underlies human physiology, evolution, and disease. Functional association studies currently ignore millions of bases that span each centromeric region and acrocentric short arm. These regions are enriched in long arrays of tandem repeats, or satellite DNAs, that are known to vary extensively in copy number and repeat structure in the human population. Satellite sequence variation in the human genome is often so large that it is detected cytogenetically, yet due to the lack of a reference assembly and informatics tools to measure this variability, contemporary high-resolution disease association studies are unable to detect causal variants in these regions. Nevertheless, recently uncovered associations between satellite DNA variation and human disease support that these regions present a substantial and biologically important fraction of human sequence variation. Therefore, there is a pressing and unmet need to detect and incorporate this uncharacterized sequence variation into broad studies of human evolution and medical genomics. Here I discuss the current knowledge of satellite DNA variation in the human genome, focusing on centromeric satellites and their potential implications for disease.

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The molecular structure, chromosomal organization, and interspecies distribution of a family of tandemly repeated DNA sequences of Antirrhinum majus L.

Genome ◽

10.1139/g96-033 ◽

1996 ◽

Vol 39 (2) ◽

pp. 243-248 ◽

Cited By ~ 7

Author(s):

Thomas Schmidt ◽

Jörg Kudla

Keyword(s):

In Situ Hybridization ◽

Dna Sequences ◽

Satellite Dna ◽

Antirrhinum Majus ◽

Repeated Dna ◽

Satellite Dnas ◽

Repeated Dna Sequences ◽

The North ◽

Tandemly Repeated Dna

Monomers of a major family of tandemly repeated DNA sequences of Antirrhinum majus have been cloned and characterized. The repeats are 163–167 bp long, contain on average 60% A + T residues, and are organized in head-to-tail orientation. According to site-specific methylation differences two subsets of repeating units can be distinguished. Fluorescent in situ hybridization revealed that the repeats are localized at centromeric regions of six of the eight chromosome pairs of A. majus with substantial differences in array size. The monomeric unit shows no homologies to other plant satellite DNAs. The repeat exists in a similar copy number and conserved size in the genomes of six European species of the genus Antirrhinum. Tandemly repeated DNA sequences with homology to the cloned monomer were also found in the North American section Saerorhinum, indicating that this satellite DNA might be of ancient origin and was probably already present in the ancestral genome of both sections. Key words : Antirrhinum majus, satellite DNA, repetitive DNA, methylation, in situ hybridization.

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Satellite DNA in Plants: More than Just Rubbish

Cytogenetic and Genome Research ◽

10.1159/000437008 ◽

2015 ◽

Vol 146 (2) ◽

pp. 153-170 ◽

Cited By ~ 64

Author(s):

Manuel A. Garrido-Ramos

Keyword(s):

Dna Sequences ◽

Satellite Dna ◽

Dna Repeats ◽

Satellite Dnas ◽

Factors Affecting ◽

Functional Roles ◽

Tandem Repeat Sequences ◽

Satellite Repeats ◽

History Of ◽

Main Components

For decades, satellite DNAs have been the hidden part of genomes. Initially considered as junk DNA, there is currently an increasing appreciation of the functional significance of satellite DNA repeats and of their sequences. Satellite DNA families accumulate in the heterochromatin in different parts of the eukaryotic chromosomes, mainly in pericentromeric and subtelomeric regions, but they also span the functional centromere. Tandem repeat sequences may spread from subtelomeric to interstitial loci, leading to the formation of chromosome-specific loci or to the accumulation in equilocal sites in different chromosomes. They also appear as the main components of the heterochromatin in the sex-specific region of sex chromosomes. Satellite DNA, required for chromosome organization, also plays a role in pairing and segregation. Some satellite repeats are transcribed and can participate in the formation and maintenance of heterochromatin structure and in the modulation of gene expression. In addition to the identification of the different satellite DNA families, their characteristics and location, we are interested in determining their impact on the genomes, by identifying the mechanisms leading to their appearance and amplification as well as in understanding how they change over time, the factors affecting these changes, and the influence exerted by the evolutionary history of the organisms. On the other hand, satellite DNA sequences are rapidly evolving sequences that may cause reproductive barriers between organisms and promote speciation. The accumulation of experimental data collected in recent years and the emergence of new approaches based on next-generation sequencing and high-throughput genome analysis are opening new perspectives that are changing our understanding of satellite DNA. This review examines recent data to provide a timely update on the overall information gathered about this part of the genome, focusing on the advances in the knowledge of its origin, its evolution, and its potential functional roles.

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Sequence Analysis and FISH Mapping of Four Satellite DNA Families among Cervidae

Genes ◽

10.3390/genes11050584 ◽

2020 ◽

Vol 11 (5) ◽

pp. 584

Author(s):

Miluse Vozdova ◽

Svatava Kubickova ◽

Halina Cernohorska ◽

Jan Fröhlich ◽

Natália Martínková ◽

...

Keyword(s):

Dna Sequences ◽

Satellite Dna ◽

Phylogenetic Trees ◽

In Situ Hybridisation ◽

Gc Content ◽

Copy Number Variations ◽

Binding Motif ◽

Fluorescence In Situ Hybridisation ◽

Chromosomal Distribution ◽

Satellite Dnas

Centromeric and pericentromeric chromosome regions are occupied by satellite DNA. Satellite DNAs play essential roles in chromosome segregation, and, thanks to their extensive sequence variability, to some extent, they can also be used as phylogenetic markers. In this paper, we isolated and sequenced satellite DNA I-IV in 11 species of Cervidae. The obtained satellite DNA sequences and their chromosomal distribution were compared among the analysed representatives of cervid subfamilies Cervinae and Capreolinae. Only satI and satII sequences are probably present in all analysed species with high abundance. On the other hand, fluorescence in situ hybridisation (FISH) with satIII and satIV probes showed signals only in a part of the analysed species, indicating interspecies copy number variations. Several indices, including FISH patterns, the high guanine and cytosine (GC) content, and the presence of centromere protein B (CENP-B) binding motif, suggest that the satII DNA may represent the most important satellite DNA family that might be involved in the centromeric function in Cervidae. The absence or low intensity of satellite DNA FISH signals on biarmed chromosomes probably reflects the evolutionary reduction of heterochromatin following the formation of chromosome fusions. The phylogenetic trees constructed on the basis of the satellite I-IV DNA relationships generally support the present cervid taxonomy.

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Satellite DNA at the Centromere is Dispensable for Segregation Fidelity

Genes ◽

10.3390/genes10060469 ◽

2019 ◽

Vol 10 (6) ◽

pp. 469 ◽

Cited By ~ 2

Author(s):

Roberti ◽

Bensi ◽

Mazzagatti ◽

Piras ◽

Nergadze ◽

...

Keyword(s):

Dna Sequences ◽

Satellite Dna ◽

Tandem Repeats ◽

Micronucleus Assay ◽

Chromosome 11 ◽

Chromosome 13 ◽

Primary Fibroblasts ◽

Mitotic Stress ◽

And Behavior

The typical vertebrate centromeres contain long stretches of highly repeated DNA sequences (satellite DNA). We previously demonstrated that the karyotypes of the species belonging to the genus Equus are characterized by the presence of satellite-free and satellite-based centromeres and represent a unique biological model for the study of centromere organization and behavior. Using horse primary fibroblasts cultured in vitro, we compared the segregation fidelity of chromosome 11, whose centromere is satellite-free, with that of chromosome 13, which has similar size and a centromere containing long stretches of satellite DNA. The mitotic stability of the two chromosomes was compared under normal conditions and under mitotic stress induced by the spindle inhibitor, nocodazole. Two independent molecular-cytogenetic approaches were used—the interphase aneuploidy analysis and the cytokinesis-block micronucleus assay. Both assays were coupled to fluorescence in situ hybridization with chromosome specific probes in order to identify chromosome 11 and chromosome 13, respectively. In addition, we tested if the lack of centromeric satellite DNA affected chromatid cohesion under normal and stress conditions. We demonstrated that, in our system, the segregation fidelity of a chromosome is not influenced by the presence of long stretches of tandem repeats at its centromere. To our knowledge, the present study is the first analysis of the mitotic behavior of a natural satellite-free centromere.

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Comparative analysis of 1.688 satellite DNA on D. melanogaster species subgroup provides new insights of its pervasive presence throughout both chromatin domains and reveals a recent horizontal transfer event.

10.1101/277129 ◽

2018 ◽

Author(s):

Leonardo Gomes De Lima ◽

Gustavo C. S. Kuhn

Keyword(s):

Phylogenetic Analysis ◽

Comparative Analysis ◽

X Chromosome ◽

Satellite Dna ◽

Horizontal Transfer ◽

Tandem Repeats ◽

Specific Pattern ◽

Chromosome X ◽

Transfer Event ◽

Species Specific

The 1.688 satellite DNA is present in the genome of Drosophila species from the melanogaster subgroup and has never been detected in species outside this subgroup. We investigated the presence and evolution of the 1.688 satDNA in all Drosophila genomes sequenced so far. Blast searches showed that 1.688 repeats are virtually confined to species from the melanogaster subgroup. Phylogenetic analysis of ~6,500 repeats extracted from D. melanogaster , D. simulans , D. sechellia , D. yakuba and D. erecta revealed the presence of 1.688 family on heterochromatin and euchromatin of all five species. Heterochromatic copies revealed a concerted mode of evolution and a species-specific pattern. Oppositely, euchromatic copies lack species-specific or array-specific pattern. Euchromatic arrays also showed a high number of insertions on 5Kb upstream/downstream of genes and in intronic regions. Unexpectedly, we found an array with at least three full 1.688 tandem repeats in the genome of D. willistoni . These repeats were highly similar to the ones present in the chromosome X of D. melanogaster , although both species have diverged from each other more than 35Mya, suggesting that 1.688 repeats from the X chromosome of D. melanogaster moved to D. willistoni by a recent horizontal transfer event.

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Molecular Cytogenetic Mapping of Satellite DNA Sequences in Aegilops geniculata and Wheat

Cytogenetic and Genome Research ◽

10.1159/000447471 ◽

2016 ◽

Vol 148 (4) ◽

pp. 314-321 ◽

Cited By ~ 2

Author(s):

Dal-Hoe Koo ◽

Vijay K. Tiwari ◽

Eva Hřibová ◽

Jaroslav Doležel ◽

Bernd Friebe ◽

...

Keyword(s):

Dna Sequences ◽

Satellite Dna ◽

Chromosome Identification ◽

Genome Chromosome ◽

Satellite Dnas ◽

Efficient System ◽

Aegilops Geniculata ◽

Alien Gene ◽

Homoeologous Relationships ◽

M Genome

Fluorescence in situ hybridization (FISH) provides an efficient system for cytogenetic analysis of wild relatives of wheat for individual chromosome identification, elucidation of homoeologous relationships, and for monitoring alien gene transfers into wheat. This study is aimed at developing cytogenetic markers for chromosome identification of wheat and Aegilops geniculata (2n = 4x = 28, UgUgMgMg) using satellite DNAs obtained from flow-sorted chromosome 5Mg. FISH was performed to localize the satellite DNAs on chromosomes of wheat and selected Aegilops species. The FISH signals for satellite DNAs on chromosome 5Mg were generally associated with constitutive heterochromatin regions corresponding to C-band-positive chromatin including telomeric, pericentromeric, centromeric, and interstitial regions of all the 14 chromosome pairs of Ae. geniculata. Most satellite DNAs also generated FISH signals on wheat chromosomes and provided diagnostic chromosome arm-specific cytogenetic markers that significantly improved chromosome identification in wheat. The newly identified satellite DNA CL36 produced localized Mg genome chromosome-specific FISH signals in Ae. geniculata and in the M genome of the putative diploid donor species Ae. comosa subsp. subventricosa but not in Ae. comosa subsp. comosa, suggesting that the Mg genome of Ae. geniculata was probably derived from subsp. subventricosa.

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