High-throughput analysis of the satellitome revealed enormous diversity of satellite DNAs in the neo-Y chromosome of the cricket Eneoptera surinamensis

Palacios-Gimenez, Octavio M.; Dias, Guilherme B.; Lima, Leonardo Gomes de; Kuhn, Gustavo C. S.; Ramos, Ercy M. C.; Martins, Cesar; Cabral-de-Mello, Diogo Cavalcanti

doi:10.1038/s41598-017-06822-8

Cited by 53 publications

(54 citation statements)

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“…Nevertheless, high-throughput sequencing contributed significantly to increase our knowledge regarding satDNA sequences [63]. Next generation sequencing (NGS; e.g., Illumina), allied to newly developed bioinformatics tools capable of identifying satDNA sequences in unassembled data (e.g., RepeatExplorer) [64][65][66], helped uncover the extent of satDNAs present in the genome of different species, revealing unpredicted levels of satDNA diversity (e.g., [34,[67][68][69][70][71]). For instances, 62 satDNA families were identified in the genome of the migratory locust, leading to the coining of the term 'satellitome' to refer to the whole collection of satDNA families found in a single genome [34], a part of the 'repeatome', a term proposed previously [33] to refer to the collection of all repetitive sequences in a genome (TEs, satDNAs, etc.).…”

Section: Satdna Features and Organization In The Genome And Chromosommentioning

confidence: 99%

Decoding the Role of Satellite DNA in Genome Architecture and Plasticity—An Evolutionary and Clinical Affair

Louzada

Lopes

Ferreira

et al. 2020

Genes

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Repetitive DNA is a major organizational component of eukaryotic genomes, being intrinsically related with their architecture and evolution. Tandemly repeated satellite DNAs (satDNAs) can be found clustered in specific heterochromatin-rich chromosomal regions, building vital structures like functional centromeres and also dispersed within euchromatin. Interestingly, despite their association to critical chromosomal structures, satDNAs are widely variable among species due to their high turnover rates. This dynamic behavior has been associated with genome plasticity and chromosome rearrangements, leading to the reshaping of genomes. Here we present the current knowledge regarding satDNAs in the light of new genomic technologies, and the challenges in the study of these sequences. Furthermore, we discuss how these sequences, together with other repeats, influence genome architecture, impacting its evolution and association with disease.

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Section: Satdna Features and Organization In The Genome And Chromosommentioning

confidence: 99%

Decoding the Role of Satellite DNA in Genome Architecture and Plasticity—An Evolutionary and Clinical Affair

Louzada

Lopes

Ferreira

et al. 2020

Genes

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“…Since they are composed of tandemly repeated sequences, satDNAs comprise long matrices located in highly compacted heterochromatin, generally in the centromeres and telomeres of the chromosomes, although they have also been reported in euchromatic regions [López-Flores and Garrido-Ramos, 2012]. In addition, there are specific sat-DNAs present in certain chromosomes, for example in sex chromosomes or B chromosomes [Mestriner et al, 2000;Ziegler et al, 2003;Vittorazzi et al, 2014;Ruiz-Ruano et al, 2016;Palacios-Gimenez et al, 2017;Gatto et al, 2018].…”

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confidence: 99%

Great Abundance of Satellite DNA in <b><i>Proceratophrys</i></b> (Anura, Odontophrynidae) Revealed by Genome Sequencing

Silva

Destro

Gazoni

et al. 2020

Cytogenet Genome Res

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Most eukaryotic genomes contain substantial portions of repetitive DNA sequences. These are located primarily in highly compacted heterochromatin and, in many cases, are one of the most abundant components of the sex chromosomes. In this sense, the anuran Proceratophrys boiei represents an interesting model for analyses on repetitive sequences by means of cytogenetic techniques, since it has a karyotype with large blocks of heterochromatin and a ZZ/ZW sex chromosome system. The present study describes, for the first time, families of satellite DNA (satDNA) in the frog P. boiei. Its genome size was estimated at 1.6 Gb, of which 41% correspond to repetitive sequences, including satDNAs, rDNAs, transposable elements, and other elements characterized as non-repetitive. The satDNAs were mapped by FISH in the centromeric and pericentromeric regions of all chromosomes, suggesting a possible involvement of these sequences in centromere function. SatDNAs are also present in the W sex chromosome, occupying the entire heterochromatic area, indicating a probable contribution of this class of repetitive DNA to the differentiation of the sex chromosomes in this species. This study is a valuable contribution to the existing knowledge on repetitive sequences in amphibians. We show the presence of repetitive DNAs, especially satDNAs, in the genome of P. boiei that might be of relevance in genome organization and regulation, setting the stage for a deeper functional genome analysis of Proceratophrys.

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“…For example, despite shared satellites at centromere loci across autosomes, the distribution of satellites varies across the X and Y chromosomes of wallabies (Bulazel, Ferreri, Eldridge, & O'Neill, ) (Figure ). Examples of novel transposable element and/or satellite distribution across sex chromosomes have been reported in many systems, including plants (Charlesworth, ; Cunado et al., ; Hobza et al., , ; Mariotti, Manzano, Kejnovsky, Vyskot, & Jamilena, ; Mariotti et al., ; Navajas‐Pérez et al., ; Shibata, Hizume, & Kuroki, , ; Steflova et al., ; Vyskot & Hobza, ), insects (Blackmon, Ross, & Bachtrog, ; DiBartolomeis, Tartof, & Jackson, ; Khost et al., ; Kuhn & Heslop‐Harrison, ; Palacios‐Gimenez et al., ; Steinemann & Steinemann, ) and vertebrates (Bulazel et al., ; Cioffi, Camacho, & Bertollo, ; Cioffi, Kejnovsky, & Bertollo, ; Cioffi, Molina, Moreira‐Filho, & Bertollo, ; Delany, Gessaro, Rodrigue, & Daniels, ; Ezaz & Deakin, ; Forster et al., ; Kawai et al., ; Kortschak, Tsend‐Ayush, & Grutzner, ; Macdonald et al., ; Miyaki, Hanotte, Wajntal, & Burke, ; Murtagh et al., ; de Oliveira et al., ; Pokorna, Kratochvil, & Kejnovsky, ; Suda, Uno, Mori, Matsuda, & Nakamura, ; Tomaszkiewicz, Medvedev, & Makova, ; Tone, Sakaki, Hashiguchi, & Mizuno, ; Wilson & Makova, ,b; Young, O'Meally, Sarre, Georges, & Ezaz, ), including human (Lander et al., ; Miga et al., ; Ross et al., ; Skaletsky et al., ).…”

Section: Sex Chromosome Repeats and Hybrid Incompatibilitymentioning

confidence: 99%

Sex chromosome repeats tip the balance towards speciation

O’Neill

2018

Molecular Ecology

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Because sex chromosomes, by definition, carry genes that determine sex, mutations that alter their structural and functional stability can have immediate consequences for the individual by reducing fertility, but also for a species by altering the sex ratio. Moreover, the sex-specific segregation patterns of heteromorphic sex chromosomes make them havens for selfish genetic elements that not only create suboptimal sex ratios but can also foster sexual antagonism. Compensatory mutations to mitigate antagonism or return sex ratios to a Fisherian optimum can create hybrid incompatibility and establish reproductive barriers leading to species divergence. The destabilizing influence of these selfish elements is often manifest within populations as copy number variants (CNVs) in satellite repeats and transposable elements (TE) or as CNVs involving sex-determining genes, or genes essential to fertility and sex chromosome dosage compensation. This review catalogs several examples of well-studied sex chromosome CNVs in Drosophilids and mammals that underlie instances of meiotic drive, hybrid incompatibility and disruptions to sex differentiation and sex chromosome dosage compensation. While it is difficult to pinpoint a direct cause/effect relationship between these sex chromosome CNVs and speciation, it is easy to see how their effects in creating imbalances between the sexes, and the compensatory mutations to restore balance, can lead to lineage splitting and species formation.

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High-throughput analysis of the satellitome revealed enormous diversity of satellite DNAs in the neo-Y chromosome of the cricket Eneoptera surinamensis

Cited by 53 publications

References 80 publications

Decoding the Role of Satellite DNA in Genome Architecture and Plasticity—An Evolutionary and Clinical Affair

Decoding the Role of Satellite DNA in Genome Architecture and Plasticity—An Evolutionary and Clinical Affair

Great Abundance of Satellite DNA in <b><i>Proceratophrys</i></b> (Anura, Odontophrynidae) Revealed by Genome Sequencing

Sex chromosome repeats tip the balance towards speciation

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