Single-molecule sequencing resolves the detailed structure of complex satellite DNA loci in <i>Drosophila melanogaster</i>

Khost, Danielle E.; Eickbush, Danna G.; Larracuente, Amanda M.

doi:10.1101/gr.213512.116

Cited by 95 publications

(123 citation statements)

References 74 publications

(105 reference statements)

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“…To prepare the data for cluster age estimation, we extracted repeat monomers from the assemblies of D. melanogaster [2] and each species of the simulans clade [3]. We aligned repeats for each cluster using ClustalO [4] and MUSCLE [5], followed by manual curation of alignments to correct for mis-alignment or mis-annotations in Geneious v8.1.6.…”

Section: Cluster Age Estimationmentioning

confidence: 99%

Dynamic Evolution of Euchromatic Satellites on the X Chromosome in Drosophila melanogaster and the simulans Clade

Sproul

Khost

Eickbush

et al. 2020

Molecular Biology and Evolution

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Satellite DNAs (satDNAs) are among the most dynamically evolving components of eukaryotic genomes and play important roles in genome regulation, genome evolution, and speciation. Despite their abundance and functional impact, we know little about the evolutionary dynamics and molecular mechanisms that shape satDNA distributions in genomes. Here, we use high-quality genome assemblies to study the evolutionary dynamics of two complex satDNAs, Rsp-like and 1.688 g/cm3, in Drosophila melanogaster and its three nearest relatives in the simulans clade. We show that large blocks of these repeats are highly dynamic in the heterochromatin, where their genomic location varies across species. We discovered that small blocks of satDNA that are abundant in X chromosome euchromatin are similarly dynamic, with repeats changing in abundance, location, and composition among species. We detail the proliferation of a rare satellite (Rsp-like) across the X chromosome in D. simulans and D. mauritiana. Rsp-like spread by inserting into existing clusters of the older, more abundant 1.688 satellite, in events likely facilitated by microhomology-mediated repair pathways. We show that Rsp-like is abundant on extrachromosomal circular DNA in D. simulans, which may have contributed to its dynamic evolution. Intralocus satDNA expansions via unequal exchange and the movement of higher order repeats also contribute to the fluidity of the repeat landscape. We find evidence that euchromatic satDNA repeats experience cycles of proliferation and diversification somewhat analogous to bursts of transposable element proliferation. Our study lays a foundation for mechanistic studies of satDNA proliferation and the functional and evolutionary consequences of satDNA movement.

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Section: Cluster Age Estimationmentioning

confidence: 99%

Dynamic Evolution of Euchromatic Satellites on the X Chromosome in Drosophila melanogaster and the simulans Clade

Sproul

Khost

Eickbush

et al. 2020

Molecular Biology and Evolution

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“…For non-model organisms, assemblies often contain even less information making the study of repetitive regions laborious (Peona et al, 2018). The availability of thirdgeneration long reads opens the way to solve genomic and evolutionary questions targeting satellite and ribosomal DNAs, such as array length, abundance and organisation in higher-15 order structures or head-to-head arrangements (Sevim et al, 2016, Khost et al, 2017, Symonová et al, 2017, Lower et al, 2018, Cechova et al, 2019, Vondrak et al, 2019. For C. quinoa, we identified arrays of the satellite families ChenSat-1a, ChenSat-1b, ChenSat-2b, ChenSat-2c, ChenSat-2d, and ChenSat-2e on SMRT reads; all were arranged in short or long homogeneous arrays, but also in structures of higher order (ChenSat-1a, ChenSat-1b, ChenSat-2c, and ChenSat-2e) and head-to-head arrangements (ChenSat-1a, ChenSat-2b, and ChenSat-2e).…”

Section: Next-and Third-generation Sequence Reads Give An Overview Onmentioning

confidence: 99%

Satellite DNA landscapes after allotetraploidisation of quinoa (Chenopodium quinoa) reveal unique A and B subgenomes

Heitkam

Weber

Walter

et al. 2019

Preprint

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Key words: Chenopodium quinoa, polyploidy, tandem repeat, satellite DNA, 5S rDNA, fluorescent in situ hybridisation (FISH), single molecule real-time (SMRT) reads Word count: 7,901 (total without abstract, references and figure legends), divided into 754 (introduction), 3,578 (results), 2,181 (discussion), 1,164 (experimental procedures) SUMMARY If two related plant species hybridise, their genomes are combined within a single nucleus, thereby forming an allotetraploid. How the emerging plant balances two co-evolved genomes is still a matter of ongoing research. Here, we focus on satellite DNA (satDNA), the fastest turn-over sequence class in eukaryotes, aiming to trace its emergence, amplification and loss during plant speciation and allopolyploidisation. As a model, we used Chenopodium quinoa Willd. (quinoa), an allopolyploid crop with 2n=4x=36 chromosomes. Quinoa originated by hybridisation of an unknown female American Chenopodium diploid (AA genome) with an unknown male Old World diploid species (BB genome), dating back 3.3 to 6.3 million years.Applying short read clustering to quinoa (AABB), C. pallidicaule (AA), and C. suecicum (BB) whole genome shotgun sequences, we classified their repetitive fractions, and identified and characterised seven satDNA families, together with the 5S rDNA model repeat. We show unequal satDNA amplification (two families) and exclusive occurrence (four families) in the AA and BB diploids by read mapping as well as Southern, genomic and fluorescent in situ hybridisation. As C. pallidicaule harbours a unique satDNA profile, we are able to exclude it as quinoa's parental species. Using quinoa long reads and scaffolds, we detected only limited evidence of interlocus homogenisation of satDNA after allopolyploidisation, but were able to exclude dispersal of 5S rRNA genes between subgenomes. Our results exemplify the complex route of tandem repeat evolution through Chenopodium speciation and allopolyploidisation, and may provide sequence targets for the identification of quinoa's progenitors.

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“…Highly homogenized arrays of tandem repeats, known as satDNAs, are enriched in centromeric, pericentromeric, subtelomeric regions and interstitial positions (Yunis, Yasmineh 1971;Greig, Willard 1992). SatDNAs have recently been reconsidered to have various functions, such as playing roles in genome stability, chromosome segregation (Khost, Eickbush, Larracuente 2017) and even gene regulations (Tomilin 2008). Beta satDNAs were considered to be unique in the primates.…”

Section: Main Textmentioning

confidence: 99%

The wide distribution and horizontal transfers of beta satellite DNA in eukaryotes

Yang

Yuan

et al. 2019

Preprint

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Beta satellite DNA (satDNA), also known as Sau3A sequences, are repeated DNA sequences reported in human and primate genomes. It is previously thought that beta satDNAs originated in old world monkeys and bursted in great apes. In this study, we searched 7,821 genome assemblies of 3,767 eukaryotic species and found that beta satDNAs are widely distributed across eukaryotes. The four major branches of eukaryotes, animals, fungi, plants and Harosa/SAR, all have multiple clades containing beta satDNAs.These results were also confirmed by searching whole genome sequencing data (SRA) and PCR assay. Beta satDNA sequences were found in all the primate clades, as well as in Dermoptera and Scandentia, indicating that the beta satDNAs in primates might originate in the common ancestor of Primatomorpha or Euarchonta. In contrast, the widely patchy distribution of beta satDNAs across eukaryotes presents a typical scenario of multiple horizontal transfers.

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Single-molecule sequencing resolves the detailed structure of complex satellite DNA loci in Drosophila melanogaster

Cited by 95 publications

References 74 publications

Dynamic Evolution of Euchromatic Satellites on the X Chromosome in Drosophila melanogaster and the simulans Clade

Dynamic Evolution of Euchromatic Satellites on the X Chromosome in Drosophila melanogaster and the simulans Clade

Satellite DNA landscapes after allotetraploidisation of quinoa (Chenopodium quinoa) reveal unique A and B subgenomes

The wide distribution and horizontal transfers of beta satellite DNA in eukaryotes

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