Natural variation of piRNA expression affects immunity to transposable elements

Ryazansky, Sergei; Radion, Elizaveta; Mironova, Anastasia; Akulenko, Natalia; Abramov, Yuri; Morgunova, Valeriya; Kordyukova, M. Yu.; Olovnikov, Ivan; Kalmykova, Alla

doi:10.1371/journal.pgen.1006731

Cited by 27 publications

(26 citation statements)

References 71 publications

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“…localization and transposition machinery may simplify their regulation by the genome. We observed expansions of all HeT-A subfamilies and TAHRE, but not the TART elements in the longest telomere strain, which is consistent with HeT-A being more sensitive to piRNA repression than TART as suggested by [70]. Similarly, we found that TART elements are segregated from HeT-A family elements and TAHRE in the telomere.…”

Section: Is Telomere Restriction Domestication or An Evolutionary Strsupporting

confidence: 87%

Rapid evolution at the Drosophila telomere: transposable element dynamics at an intrinsically unstable locus

McGurk

Dion-Côté

Barbash

2019

Preprint

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Background: Drosophila telomeres have been maintained by three families of active transposable elements (TEs), HeT-A, TAHRE and TART, collectively referred to as HTTs, for tens of millions of years.The conservation of this arrangement contrasts with an unusually high degree of HTT interspecific variation. While the impacts of conflict and domestication are often invoked to explain HTT variation, the telomeres are unstable structures such that neutral mutational processes and evolutionary tradeoffs may also drive HTT evolution. Results:We leveraged population genomic data to analyze nearly 10,000 HTT insertions in 85 D.melanogaster genomes and compared their variation to TE families evolving under more typical dynamics. We find that distinct aspects of HTT copy number variation and sequence diversity largely reflect telomere instability, with HTT insertions being lost at much higher rates than other TEs elsewhere in the genome. However, occasional copy number expansions of both HTTs and other TE families occur, highlighting that the HTTs are, like their feral cousins, typically repressed but primed to take over given the opportunity. We further find that some HTT families may be activated by the erosion of whole telomeres, suggesting the existence of HTT-specific host control mechanisms. Conclusions:Even the persistent telomere localization of HTTs may not reflect domestication, but rather a highly successful evolutionary strategy to reduce their impact on the host genome. We propose that HTT evolution is driven by multiple processes including domestication, genetic conflict, niche specialization, and telomere instability, with the latter two being previously underappreciated and likely predominant.

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Section: Is Telomere Restriction Domestication or An Evolutionary Strsupporting

confidence: 87%

Rapid evolution at the Drosophila telomere: transposable element dynamics at an intrinsically unstable locus

McGurk

Dion-Côté

Barbash

2019

Preprint

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“…The R strain w K , which was used for the I-TG transgenesis, is a strong reactive strain, meaning that a very high level of I-element transposition was observed when introducing functional I-elements by a cross between w K females and inducer males. In w K ovaries, only a minimal amount of ancestral I-derived piRNAs is produced [19,24,40] (Tables S3 and S4). One could argue that initially, the chromatin structure and piRNA production from the I-transgenes in all strains were the same, although later, in the course of the strain-specific history, the transgenes in the 2.1 s and 2.4 s strains became stronger, which resulted in higher Rhi occupancy and more efficient piRNA production.…”

Section: Transgenic Pirna Cluster Establishment Is Independent Of Higmentioning

confidence: 99%

“…We found that the increase in the level of piRNAs targeting I-TG transgenes does not stimulate additional changes of the chromatin state or piRNA production by the transgenes. The study of paternal transgene inheritance by crossing transgenic males with w K females whose oocyte cytoplasm is the poorest in I-specific piRNAs [24] suggests that heterochromatinization and piRNA production at the target locus are activated by a minimum threshold level of complementary piRNAs.…”

Section: Introductionmentioning

confidence: 99%

Epigenetic Requirements for Triggering Heterochromatinization and Piwi-Interacting RNA Production from Transgenes in the Drosophila Germline

Komarov

Akulenko

Brasset

et al. 2020

Cells

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Transgenes containing a fragment of the I retrotransposon represent a powerful model of piRNA cluster de novo formation in the Drosophila germline. We revealed that the same transgenes located at different genomic loci form piRNA clusters with various capacity of small RNA production. Transgenic piRNA clusters are not established in piRNA pathway mutants. However, in the wild-type context, the endogenous ancestral I-related piRNAs heterochromatinize and convert the I-containing transgenes into piRNA-producing loci. Here, we address how the quantitative level of piRNAs influences the heterochromatinization and piRNA production. We show that a minimal amount of maternal piRNAs from ancestral I-elements is sufficient to form the transgenic piRNA clusters. Supplemental piRNAs stemming from active I-element copies do not stimulate additional chromatin changes or piRNA production from transgenes. Therefore, chromatin changes and piRNA production are initiated by a minimum threshold level of complementary piRNAs, suggesting a selective advantage of prompt cell response to the lowest level of piRNAs. It is noteworthy that the weak piRNA clusters do not transform into strong ones after being targeted by abundant I-specific piRNAs, indicating the importance of the genomic context for piRNA cluster establishment. Analysis of ovarian transcription profiles suggests that regions facilitating convergent transcription favor the formation of transgenic piRNA clusters.

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“…Thus, the telomeres need to produce both the intact TE mRNA required for telomere elongation, as well as piRNAs that target these TE mRNA in order to regulate optimal telomere length. Indeed, altering this balance can lead to disruption of telomere length control (3,33).…”

Section: Introductionmentioning

confidence: 99%

Key role of piRNAs in telomeric chromatin maintenance and telomere nuclear positioning inDrosophilagermline

Radion

Morgunova

Ryazansky

et al. 2017

Preprint

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Telomeric small RNAs related to PIWI-interacting RNAs (piRNAs) were discovered in different species, however, their role in germline-specific telomere function remains poorly understood. Using a Drosophila model, we show that the piRNA pathway provides a strong germline-specific mechanism of telomere homeostasis. We show that telomeric retrotransposon arrays belong to a unique class of dual-strand piRNA clusters whose transcripts, required for telomere elongation, serve simultaneously as piRNA precursors and their only targets. However, the ability to produce piRNAs and bind Rhino -a germlinespecific homolog of heterochromatic protein 1 (HP1) -varies along telomeres. Most likely, this heterogeneity is determined by the peculiarities of telomeric retrotransposons themselves. piRNAs play a pivotal role in the establishment and maintenance of telomeric and subtelomeric chromatin in the germline facilitating loading of HP1 and histone 3 lysine 9 trimethylation mark -highly conservative telomere components -at different telomeric regions. piRNA pathway disruption results in telomere dysfunction characterized by a loss of heterochromatic components and translocation of telomeres from the periphery to the nuclear interior but does not affect the telomere end capping.

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Natural variation of piRNA expression affects immunity to transposable elements

Cited by 27 publications

References 71 publications

Rapid evolution at the Drosophila telomere: transposable element dynamics at an intrinsically unstable locus

Rapid evolution at the Drosophila telomere: transposable element dynamics at an intrinsically unstable locus

Epigenetic Requirements for Triggering Heterochromatinization and Piwi-Interacting RNA Production from Transgenes in the Drosophila Germline

Key role of piRNAs in telomeric chromatin maintenance and telomere nuclear positioning inDrosophilagermline

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