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Increasing evidence indicates that non-DNA sequence-based epigenetic information can be inherited across several generations in organisms ranging from yeast to plants to humans. This raises the possibility of heritable ‘epimutations’ contributing to heritable phenotypic variation and thus to evolution. Recent work has shed light on both the signals that underpin these epimutations, including DNA methylation, histone modifications and non-coding RNAs, and the mechanisms by which they are transmitted across generations at the molecular level. These mechanisms can vary greatly among species and have a more limited effect in mammals than in plants and other animal species. Nevertheless, common principles are emerging, with transmission occurring either via direct replicative mechanisms or indirect reconstruction of the signal in subsequent generations. As these processes become clearer we continue to improve our understanding of the distinctive features and relative contribution of DNA sequence and epigenetic variation to heritable differences in phenotype.In this Review, Fitz-James and Cavalli discuss the diverse and often multilayered mechanisms by which transgenerational epigenetic inheritance can occur in different species.

During mitosis chromosomes reorganise into highly compact, rod-shaped forms, thought to consist of consecutive chromatin loops around a central protein scaffold. Condensin complexes are involved in chromatin compaction, but the contribution of other chromatin proteins, DNA sequence and histone modifications is less understood. A large region of fission yeast DNA inserted into a mouse chromosome was previously observed to adopt a mitotic organisation distinct from that of surrounding mouse DNA. Here, we show that a similar distinct structure is common to a large subset of insertion events in both mouse and human cells and is coincident with the presence of high levels of heterochromatic H3 lysine nine trimethylation (H3K9me3). Hi-C and microscopy indicate that the heterochromatinised fission yeast DNA is organised into smaller chromatin loops than flanking euchromatic mouse chromatin. We conclude that heterochromatin alters chromatin loop size, thus contributing to the distinct appearance of heterochromatin on mitotic chromosomes.

Transgenerational epigenetic inheritance (TEI) describes the process whereby distinct epigenetic states are transmitted between generations, resulting in heritable gene expression and phenotypic differences that are independent of DNA sequence variation. Chromatin modifications have been demonstrated to be important in TEI; however, the extent to which they require other signals to establish and maintain epigenetic states is still unclear. Here we investigate whether small non-coding RNAs contribute to different epigenetic states of the Fab2L transgene in Drosophila triggered by transient long-range chromosomal contacts, which requires Polycomb complex activity to deposit the H3K27me3 modification for long-term TEI. By analysing mutants deficient in small non-coding RNAs, high-throughput sequencing data, long-range chromosomal contacts and gene expression, we demonstrate that small non-coding RNAs do not contribute directly to initiation or maintenance of silencing. However, we uncover an indirect role for microRNA expression in transgene silencing through effects on the Polycomb group gene Pleiohomeotic . Additionally, we show that a commonly used marker gene, Stubble ( Sb ), affects Pleiohomeotic expression, which may be important in interpreting experiments assaying Polycomb function in Drosophila development. By ruling out a plausible candidate for TEI at the Fab2L transgene, our work highlights the variability in different modes of TEI across species.

Non-genetic information can be inherited across generations by the process of Transgenerational Epigenetic Inheritance (TEI). TEI can be established by various triggering events, including transient genetic perturbations. In Drosophila, hemizygosity of the Fab-7 regulatory element triggers inheritance of the histone mark H3K27me3 at a homologous locus on another chromosome, resulting in heritable epigenetic differences in eye colour. By mutating transcription factor binding sites within the Fab-7 element, we demonstrate the importance of two proteins in the establishment and maintenance of TEI: GAGA-factor and Pleiohomeotic. We show that these proteins function by recruiting the Polycomb Repressive Complex 2 and by mediating interchromosomal chromatin contacts between Fab-7 and its homologous locus. Finally, using an in vivo synthetic biology system to induce them, we show that chromatin contacts alone can establish TEI, providing a mechanism by which hemizygosity of one locus can establish epigenetic memory at another in trans through long-distance chromatin contacts.

During mitosis chromosomes reorganise into highly compact, rod-shaped forms, thought to consist of consecutive chromatin loops around a central protein scaffold. Condensin complexes are involved in chromatin compaction, but the contribution of other chromatin proteins, DNA sequence and histone modifications is less understood. A large region of fission yeast DNA inserted into a mouse chromosome was previously observed to adopt a mitotic organisation distinct from that of surrounding mouse DNA. Here we show that a similar distinct structure is common to a large subset of insertion events in both mouse and human cells and is coincident with the presence of high levels of heterochromatic H3 lysine 9 trimethylation (H3K9me3). Hi-C and microscopy indicate that the heterochromatinised fission yeast DNA is organised into smaller chromatin loops than flanking euchromatic mouse chromatin. We conclude that heterochromatin alters chromatin loop size, thus contributing to the distinct appearance of heterochromatin on mitotic chromosomes, such as at centromeres.

In order to contain many millions, or even billions of base pairs within every nucleus of a eukaryotic cell, DNA must be extensively packaged. This is achieved by association of DNA with packaging proteins, resulting in the formation of chromatin, which can lead to various degrees of compaction. The most extreme form of compaction is the highly condensed mitotic chromosome, formation of which is necessary for proper resolution and segregation of the genetic material during cell division. However, the exact nature of the structure of chromatin within the mitotic chromosome and the factors which regulate it remain subjects of debate and continued investigation. The hybrid cell line F1.1 presents a unique tool for the study of mitotic chromosome structure. This mouse cell line has been observed to present a distinct chromatin structure in mitosis assembled over a large region of DNA inserted into one of its chromosomes and originating from the fission yeast Schizosaccharomyces pombe. Direct comparison of the structure of this distinct region of chromatin with that of the adjacent endogenous chromatin could provide insight into the nature of mitotic chromosome structure as well as the properties of the chromatin which are influencing this structure. Microscopy and Hi-C analyses showed that the mitotic chromatin organising or \"scaffold\" proteins are not altered over the region of S. pombe chromatin, but that the amount of chromatin organised around these proteins is diminished. In accordance with the \"radial-loop\" model of mitotic chromosome structure, we put forward a model whereby the S. pombe chromatin is organised into smaller chromatin loops around a constant organising scaffold. Examination of the histone post-translational modifications over the region of S. pombe chromatin revealed it to be highly heterochromatic, with high levels of H3K9me3 and associated factors such as HP1α and 5meC, and low levels of activating marks. Generation of further mammalian - S. pombe fusion cell lines recapitulated both the distinct mitotic structure and the heterochromatic profile of the inserted S. pombe chromatin. However, insertion of S. pombe DNA into a mouse cell by transfection rather than fusion resulted in a large region of S. pombe DNA that lacked both a distinct structure and heterochromatin. These results suggest that H3K9me3- mediated heterochromatin may influence the structure of chromatin in mitosis, leading to an organisation into smaller chromatin loops than non-heterochromatic regions.

Transgenerational epigenetic inheritance (TEI) describes the process where distinct epigenetic states may be transmitted between generations, resulting in stable gene expression and phenotypic differences between individuals that persist independently of DNA sequence variation. Chromatin modifications have been demonstrated as important in TEI, however, the extent to which they require other signals to establish and maintain epigenetic states is still unclear. Here we investigate whether small non-coding RNAs contribute to different epigenetic states of the Fab2L transgene in Drosophila triggered by transient chromatin contacts, which requires Polycomb complex activity to deposit the H3K27me3 modification for long-term TEI. Using mutants deficient in known small non-coding RNAs, high throughput sequencing, investigation of chromatin conformation and gene expression analysis we demonstrate that small non-coding RNAs do not contribute directly to initiation or maintenance of silencing. However, we uncover an indirect role for microRNA expression in transgene silencing through effects on Polycomb complex expression. Additionally, we show that a commonly used marker gene, Stubble (Sb), affects Polycomb complex expression, which may be important in interpreting experiments assaying Polycomb function in Drosophila development. By ruling out a plausible candidate for TEI at the Fab2L transgene our work highlights the variability in different modes of TEI across species.