Aneta Bulic scite author profile

BackgroundRegulation of chromatin structure involves deposition of selective histone variants into nucleosome arrays. Numerous histone H3 variants become differentially expressed by individual nanochromosomes in the course of macronuclear differentiation in the spirotrichous ciliate Stylonychia lemnae. Their biological relevance remains to be elucidated.ResultsWe show that the differential assembly of H3 variants into chromatin is strongly correlated with the functional separation of chromatin structures in developing macronuclei during sexual reproduction in Stylonychia, thus probably determining the fate of specific sequences. Specific H3 variants approximately 15 kDa or 20 kDa in length are selectively targeted by post-translational modifications. We found that only the 15 kDa H3 variants including H3.3 and H3.5, accumulate in the early developing macronucleus, and these also occur in mature macronuclei. H3.7 is a 20 kDa variant that specifically becomes enriched in macronuclear anlagen during chromosome polytenization. H3.7, acetylated at lysine-32 (probably equivalent to lysine-36 of most H3 variants), is specifically associated with a sequence class that is retained in the mature macronucleus and therefore does not undergo developmental DNA elimination. H3.8 is another 20 kDa variant that is restricted to the micronucleus. H3.8 is selectively targeted by lysine methylation and by serine or threonine phosphorylation. Intriguingly, the expression and chromatin localization of the histone variant H3.3 was impaired during macronuclear differentiation after RNA interference knock-down of Piwi expression.ConclusionsDifferential deposition of H3 variants into chromatin strongly correlates with the functional distinction of genomic sequence classes on the chromatin level, thus helping to determine the fate of specific DNA sequences during sexual reproduction in Stylonychia. Consequently, H3 variants are selectively targeted by post-translational modifications, possibly as a result of deviations within the recognition motifs, which allow binding of effector proteins. We propose that differential assembly of histone variants into chromatin of various nuclear types could contribute to nuclear identity, for example, during differential development of either new micronuclei or a macronuclear anlage from mitosis products of the zygote nucleus (synkaryon). The observation that the Piwi-non-coding RNA (ncRNA) pathway influences the expression and deposition of H3.3 in macronuclear anlagen indicates for the first time that selective histone variant assembly into chromatin might possibly depend on ncRNA.

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27nt-RNAs guide histone variant deposition via ‘RNA-induced DNA replication interference’ and thus transmit parental genome partitioning in Stylonychia

Postberg

Jönsson

Weil

et al. 2018

Epigenetics & Chromatin

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BackgroundDuring sexual reproduction in the unicellular ciliate Stylonychia somatic macronuclei differentiate from germline micronuclei. Thereby, programmed sequence reduction takes place, leading to the elimination of > 95% of germline sequences, which priorly adopt heterochromatin structure via H3K27me3. Simultaneously, 27nt-ncRNAs become synthesized from parental transcripts and are bound by the Argonaute protein PIWI1.ResultsThese 27nt-ncRNAs cover sequences destined to the developing macronucleus and are thought to protect them from degradation. We provide evidence and propose that RNA/DNA base-pairing guides PIWI1/27nt-RNA complexes to complementary macronucleus-destined DNA target sequences, hence transiently causing locally stalled replication during polytene chromosome formation. This spatiotemporal delay enables the selective deposition of temporarily available histone H3.4K27me3 nucleosomes at all other sequences being continuously replicated, thus dictating their prospective heterochromatin structure before becoming developmentally eliminated. Concomitantly, 27nt-RNA-covered sites remain protected.ConclusionsWe introduce the concept of ‘RNA-induced DNA replication interference’ and explain how the parental functional genome partition could become transmitted to the progeny.Electronic supplementary materialThe online version of this article (10.1186/s13072-018-0201-5) contains supplementary material, which is available to authorized users.

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A permissive chromatin structure is adopted prior to site-specific DNA demethylation of developmentally expressed genes involved in macronuclear differentiation

Bulic

Postberg

Fischer³

et al. 2013

Epigenetics & Chromatin

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BackgroundDNA methylation and demethylation are important epigenetic regulatory mechanisms in eukaryotic cells and, so far, only partially understood. We exploit the minimalistic biological ciliate system to understand the crosstalk between DNA modification and chromatin structure. In the macronucleus of these cells, the DNA is fragmented into individual short DNA molecules, each representing a functional expression and replication unit. Therefore, long range epigenomic interaction can be excluded in this system.ResultsIn the stichotrichous ciliate Stylonychia lemnae, cytosine methylation occurs in a small subset of macronuclear nanochromosomes expressed only during sexual reproduction. Methylation pattern shows similarity to that observed in fungi and Drosophila. Cytosine methylation correlates with gene activity and chromatin structure. Upon gene activation, cytosines become demethylated and a redistribution of histone post-translational modifications (PTMs) takes place. Evidence is presented that the formation of a permissive chromatin structure in the vicinity of the 5meCs precedes cytosine methylation and is probably a necessary prerequisite for their demethylation. Shortly after demethylation of cytosines occurs, the parental macronucleus degenerates, a new macronucleus is formed from a micronuclear derivative and the specific methylation pattern is transmitted from the germline micronucleus to the new macronucleus.ConclusionsWe show that very few, or even only one, discrete methylated cytosines are required to assign regulatory functions at a specific locus. Furthermore, evidence is provided that a permissive chromatin structure is probably a necessary prerequisite for the demethylation of specific cytosines. Our results allow us to propose a mechanistic model for the biological function of cytosine methylation in the ciliate cell and its regulation during the cell cycle.

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Aneta Bulic

Differential expression of histone H3 genes and selective association of the variant H3.7 with a specific sequence class in Stylonychia macronuclear development

27nt-RNAs guide histone variant deposition via ‘RNA-induced DNA replication interference’ and thus transmit parental genome partitioning in Stylonychia

A permissive chromatin structure is adopted prior to site-specific DNA demethylation of developmentally expressed genes involved in macronuclear differentiation

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