Repetitive DNA content in the maize genome is uncoupled from population stratification at SNP loci

Multicellular organisms can generate and maintain homogenous populations of cells that make up individual tissues. However, cellular processes that can disrupt homogeneity and how organisms overcome such disruption are unknown. We found that ∼100-fold differences in expression from a repetitive DNA transgene can occur between intestinal cells in Caenorhabditis elegans. These differences are caused by gene silencing in some cells and are actively suppressed by parental and zygotic factors such as the conserved exonuclease ERI-1. If unsuppressed, silencing can spread between some cells in embryos but can be repeat specific and independent of other homologous loci within each cell. Silencing can persist through DNA replication and nuclear divisions, disrupting uniform gene expression in developed animals. Analysis at single-cell resolution suggests that differences between cells arise during early cell divisions upon unequal segregation of an initiator of silencing. Our results suggest that organisms with high repetitive DNA content, which include humans, could use similar developmental mechanisms to achieve and maintain tissue homogeneity.

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Quantitative sequence characterization for repetitive DNA content in the supernumerary chromosome of the migratory locust

Chromosoma ◽

10.1007/s00412-017-0644-7 ◽

2017 ◽

Vol 127 (1) ◽

pp. 45-57 ◽

Cited By ~ 9

Author(s):

Francisco J. Ruiz-Ruano ◽

Josefa Cabrero ◽

María Dolores López-León ◽

Antonio Sánchez ◽

Juan Pedro M. Camacho

Keyword(s):

Repetitive Dna ◽

Dna Content ◽

Supernumerary Chromosome ◽

Migratory Locust ◽

Sequence Characterization

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Meiotic Drive of Chromosomal Knobs Reshaped the Maize Genome

Genetics ◽

10.1093/genetics/153.1.415 ◽

1999 ◽

Vol 153 (1) ◽

pp. 415-426 ◽

Cited By ~ 13

Author(s):

Edward S Buckler ◽

Tara L Phelps-Durr ◽

Carlyn S Keith Buckler ◽

R Kelly Dawe ◽

John F Doebley ◽

...

Keyword(s):

Repetitive Dna ◽

Genetic Linkage ◽

Genome Structure ◽

Meiotic Drive ◽

Wild Relatives ◽

Maize Genome ◽

Dna Arrays ◽

Chromosomal Position ◽

Preferential Segregation ◽

Drive Model

Abstract Meiotic drive is the subversion of meiosis so that particular genes are preferentially transmitted to the progeny. Meiotic drive generally causes the preferential segregation of small regions of the genome; however, in maize we propose that meiotic drive is responsible for the evolution of large repetitive DNA arrays on all chromosomes. A maize meiotic drive locus found on an uncommon form of chromosome 10 [abnormal 10 (Ab10)] may be largely responsible for the evolution of heterochromatic chromosomal knobs, which can confer meiotic drive potential to every maize chromosome. Simulations were used to illustrate the dynamics of this meiotic drive model and suggest knobs might be deleterious in the absence of Ab10. Chromosomal knob data from maize's wild relatives (Zea mays ssp. parviglumis and mexicana) and phylogenetic comparisons demonstrated that the evolution of knob size, frequency, and chromosomal position agreed with the meiotic drive hypothesis. Knob chromosomal position was incompatible with the hypothesis that knob repetitive DNA is neutral or slightly deleterious to the genome. We also show that environmental factors and transposition may play a role in the evolution of knobs. Because knobs occur at multiple locations on all maize chromosomes, the combined effects of meiotic drive and genetic linkage may have reshaped genetic diversity throughout the maize genome in response to the presence of Ab10. Meiotic drive may be a major force of genome evolution, allowing revolutionary changes in genome structure and diversity over short evolutionary periods.

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Comparative Performance of Two Whole Genome Capture Methodologies on Ancient DNA Illumina Libraries

10.1101/007419 ◽

2014 ◽

Author(s):

Maria Avila-Arcos ◽

Marcela Sandoval-Velasco ◽

Hannes Schroeder ◽

Meredith L Carpenter ◽

Anna-Sapfo Malaspinas ◽

...

Keyword(s):

Genome Sequencing ◽

Repetitive Dna ◽

Ancient Dna ◽

Dna Content ◽

Important Influence ◽

Whole Genome ◽

Comparative Performance ◽

Gc Composition

1. The application of whole genome capture (WGC) methods to ancient DNA (aDNA) promises to increase the efficiency of ancient genome sequencing. 2. We compared the performance of two recently developed WGC methods in enriching human aDNA within Illumina libraries built using both double-stranded (DSL) and single-stranded (SSL) build protocols. Although both methods effectively enriched aDNA, one consistently produced marginally better results, giving us the opportunity to further explore the parameters influencing WGC experiments. 3. Our results suggest that bait length has an important influence on library enrichment. Moreover, we show that WGC biases against the shorter molecules that are enriched in SSL preparation protocols. Therefore application of WGC to such samples is not recommended without future optimization. Lastly, we document the effect of WGC on other features including clonality, GC composition and repetitive DNA content of captured libraries. 4. Our findings provide insights for researchers planning to perform WGC on aDNA, and suggest future tests and optimization to improve WGC efficiency.

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Evolution of a functionally related lactate dehydrogenase and pyruvate decarboxylase pseudogene complex in maize

Genome ◽

10.1139/g99-094 ◽

1999 ◽

Vol 42 (6) ◽

pp. 1167-1175

Author(s):

Mary E Christopher ◽

Allen G Good

Keyword(s):

Lactate Dehydrogenase ◽

Binding Site ◽

Repetitive Dna ◽

Genomic Dna ◽

Pyruvate Decarboxylase ◽

Primer Binding Site ◽

Inverted Repeats ◽

Maize Genome ◽

Long Terminal Repeats ◽

Intergenic Regions

A large proportion of the maize genome is repetitive DNA (60-80%) with retrotransposons contributing significantly to the repetitive DNA component. The majority of retrotransposon DNA is located in intergenic regions and is organized in a nested fashion. Analysis of an 8.2-kb segment of maize genomic DNA demonstrated the presence of three retrotransposons of different reiteration classes in addition to lactate dehydrogenase and pyruvate decarboxylase pseudogenes. Both of the pseudogenes were located within a defective retrotransposon element (LP-like element) which possessed identical long terminal repeats (LTRs) with inverted repeats at each end, a primer binding site, a polypurine tract, and generated a 5-bp target site duplication. A model describing the events leading to the formation of the LP-like element is proposed.Key words: lactate dehydrogenase, LP-like element, pseudogene, pyruvate decarboxylase, retrotransposon.

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Repetitive DNA and chromosome evolution in plants

Philosophical Transactions of the Royal Society of London Series B Biological Sciences ◽

10.1098/rstb.1986.0004 ◽

1986 ◽

Vol 312 (1154) ◽

pp. 227-242 ◽

Cited By ~ 181

Keyword(s):

Transposable Elements ◽

Repetitive Dna ◽

Dna Sequences ◽

Dna Content ◽

Molecular Mechanisms ◽

Chromosome Structure ◽

Species Turnover ◽

Inverted Terminal Repeat ◽

Repeated Dna ◽

Higher Plant

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.

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Blm Helicase Facilitates Rapid Replication of Repetitive DNA Sequences in early Drosophila Development

10.1101/2021.06.16.448677 ◽

2021 ◽

Author(s):

Jolee M Ruchert ◽

Morgan M Brady ◽

Susan McMahan ◽

Karly J Lacey ◽

Leigh C. Latta ◽

...

Keyword(s):

Dna Repair ◽

Embryonic Development ◽

Repetitive Dna ◽

Dna Sequences ◽

Dna Content ◽

Replication Fork ◽

Replication Stress ◽

Sex Bias ◽

Repetitive Dna Sequences ◽

Cell Cycles

The absence of functional BLM DNA helicase, a member of the RecQ family of helicases, is responsible for the rare human disorder Bloom Syndrome, which results in developmental abnormalities, DNA repair defects, genomic instability, and a predisposition to cancer. In Drosophila melanogaster, the orthologous Blm protein is essential during early development when the embryo is under the control of maternal gene products. A lack of functional maternal Blm during the syncytial cell cycles of Drosophila embryonic development results in severe nuclear defects and lethality. Amongst the small fraction of embryos from Blm mutant mothers that survive to adulthood, a prominent sex-bias favors the class of flies that inherits less repetitive DNA content, which serves as an endogenous source of replication stress. This selection against repetitive DNA content reflects a role for Blm in facilitating replication through repetitive sequences during the rapid S-phases of syncytial cell cycles. During these syncytial cycles, Blm is not required for complex DNA repair; however, the progeny sex-bias resulting from the absence of maternal Blm is exacerbated by repetitive DNA sequences and by the slowing of replication fork progression, suggesting that the essential role for Blm during this stage is to manage replication fork stress brought about by impediments to fork progression. Additionally, our data suggest that Blm is only required to manage this replication stress during embryonic development, and likely only during the early, rapid syncytial cell cycles, and not at later developmental stages. These results provide novel insights into Blm function throughout development.

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