Project description:Transgenerational epigenetic inheritance (TEI), the transmission of epigenetic states between generations, has been observed in complex organisms ranging from plants to nematode worms, insects and mammals. One form of TEI that has been robustly studied is the inheritance of gene silencing. In Caenorhabditis elegans transgenerational gene silencing can be partitioned into three phases: the initiation of silencing, establishment of a heritable silencing signal within the parent individuals, and maintenance of this silencing signal within subsequent generations. Silencing involves nuclear and cytoplasmic components, and most genes involved in the process are linked to small RNA processing pathways. To date, two predicted histone methyltransferases have been implicated in the establishment of TEI, set-25 and set-32. Here, we demonstrate that the closely related paralogues set-9 and set-26 function in establishment and maintenance of TEI. We also identify a third related gene that lacks any predicted ordered domains; we name this gene intrinsically disordered protein-1 (idp-1). Strikingly, idp-1 also plays a role in establishment of TEI. SET-9 and SET-26 each contain a PHD finger and a SET domain. We show that the SET domains of SET-9 and SET-26 likely have no histone lysine methyltransferase activity, but that the PHD fingers bind trimethylated histone 3 lysine 4 (H3K4me3) in the absence of adjacent histone marks. We demonstrate that despite modelling data that suggests that set-9 and set-26 lack histone lysine methyltransferase activity, the function of both genes in TEI requires their PHD finger and SET domains. Our data confirm that the SET domain is functional and identifies three new chromatin factors required for epigenetic inheritance.

Project description:Some epigenetic modifications are inherited from one generation to the next, providing a potential mechanism for the inheritance of environmentally acquired traits. Transgenerational inheritance of RNA interference phenotypes in C. elegans provides an excellent model to study this phenomenon, and whilst studies have implicated both chromatin modifications and small RNA pathways in heritable silencing their relative contributions remain unclear. Here we demonstrate that the histone methyltransferases SET-25 and SET-32 are required for the establishment of a transgenerational silencing signal, but not for long-term maintenance of this signal between subsequent generations suggesting that transgenerational epigenetic inheritance is a multi-step process, with distinct genetic requirements for establishment and maintenance of heritable silencing. Furthermore, small RNA sequencing reveals that the abundance of secondary siRNA (thought to be the effector molecules of heritable silencing) does not correlate with silencing phenotypes. Together, our results suggest that the current mechanistic models of epigenetic inheritance are incomplete.

Project description:Transgenerational epigenetic inheritance (TEI) describes the transmission of gene-regulatory information across generations without altering DNA sequences. TEI allows priming of offspring towards changing environmental conditions and plays a role in the maintenance of gene silencing of selfish genetic elements like transposons. Small regulatory RNAs are well known to act in TEI, and can be transmitted via the male. Such inheritance via sperm requires dedicated mechanisms, as much of the cellular content is extruded during spermatogenesis. We identify a phase separation-based mechanism, which couples the paternal inheritance of a specific small RNA-bound silencing factor via S-palmitoylation to the transport of membranous organelles. Our findings uncover a thus far unknown paternal TEI mechanism, and describe a novel mode of transport of phase-separated condensates.

Project description:SET-9 and SET-26 impact transgenerational epigenetic inheritance and germline mortality through their PHD finger and SET domains

Project description:SET-9 and SET-26 impact transgenerational epigenetic inheritance and germline mortality through their PHD finger and SET domains [RNA-Seq ]

Project description:SET-9 and SET-26 impact transgenerational epigenetic inheritance and germline mortality through their PHD finger and SET domains [small RNA-seq]

Project description:Epigenetic inheritance contributes fundamentally to transgenerational physiology and fitness. Mechanistic understanding of RNA-mediated chromatin modification and transgenerational epigenetic inheritance, which in C. elegans can be triggered by exogenous double-stranded RNA (exo-dsRNA) or facilitated by endogenous small interfering RNAs (endo-siRNAs), has mainly been limited to the post-initiation phases of silencing. Indeed, the dynamic process by which nuclear RNAi engages a transcriptionally active target, before the repressive state is stably established, remains largely a mystery. Here we found that the onset of exo-dsRNA-induced nuclear RNAi is a transgenerational process, and that establishment requires SET-32, one of the three putative histone methyltransferases (HMTs) that are required for H3K9me3 deposition at the nuclear RNAi targets. We also performed multigenerational whole-genome analyses to examine the establishment of silencing at endogenous targets of germline nuclear RNAi. The nuclear Argonaute (AGO) protein HRDE-1 is essential for the maintenance of nuclear RNAi. Repairing a loss-of-function mutation in hrde-1 by CRISPR restored the silencing of endogenous targets in animals carrying wild type set-32. However, for numerous endogenous targets, repairing the hrde-1 mutation in a set-32;hrde-1 double mutant failed to restore their silencing states in up to 20 generations after the hrde-1 repair, using a similar genome editing approach. We found that despite a prominent role in the establishment of silencing, however, set-32 is completely dispensable for the maintenance of silencing once HRDE-1-dependent gene repression is established. Our study indicates that: 1) initiation and maintenance of siRNA-guided transcriptional repression are two distinct processes with different genetic requirements; and 2) the rate-limiting step of the establishment phase is a transgenerational, chromatin-based process. In addition, our study reveals a novel paradigm in which a heterochromatin factor primarily functions to promote the initiation of transgenerational silencing, expanding mechanistic understanding of the well-recognized role of heterochromatin in epigenetic maintenance.

Project description:Epigenetic inheritance contributes fundamentally to transgenerational physiology and fitness. Mechanistic understanding of RNA-mediated chromatin modification and transgenerational epigenetic inheritance, which in C. elegans can be triggered by exogenous double-stranded RNA (exo-dsRNA) or facilitated by endogenous small interfering RNAs (endo-siRNAs), has mainly been limited to the post-initiation phases of silencing. Indeed, the dynamic process by which nuclear RNAi engages a transcriptionally active target, before the repressive state is stably established, remains largely a mystery. Here we found that the onset of exo-dsRNA-induced nuclear RNAi is a transgenerational process, and that establishment requires SET-32, one of the three putative histone methyltransferases (HMTs) that are required for H3K9me3 deposition at the nuclear RNAi targets. We also performed multigenerational whole-genome analyses to examine the establishment of silencing at endogenous targets of germline nuclear RNAi. The nuclear Argonaute (AGO) protein HRDE-1 is essential for the maintenance of nuclear RNAi. Repairing a loss-of-function mutation in hrde-1 by CRISPR restored the silencing of endogenous targets in animals carrying wild type set-32. However, for numerous endogenous targets, repairing the hrde-1 mutation in a set-32;hrde-1 double mutant failed to restore their silencing states in up to 20 generations after the hrde-1 repair, using a similar genome editing approach. We found that despite a prominent role in the establishment of silencing, however, set-32 is completely dispensable for the maintenance of silencing once HRDE-1-dependent gene repression is established. Our study indicates that: 1) initiation and maintenance of siRNA-guided transcriptional repression are two distinct processes with different genetic requirements; and 2) the rate-limiting step of the establishment phase is a transgenerational, chromatin-based process. In addition, our study reveals a novel paradigm in which a heterochromatin factor primarily functions to promote the initiation of transgenerational silencing, expanding mechanistic understanding of the well-recognized role of heterochromatin in epigenetic maintenance.

Project description:Epigenetic inheritance contributes fundamentally to transgenerational physiology and fitness. Mechanistic understanding of RNA-mediated chromatin modification and transgenerational epigenetic inheritance, which in C. elegans can be triggered by exogenous double-stranded RNA (exo-dsRNA) or facilitated by endogenous small interfering RNAs (endo-siRNAs), has mainly been limited to the post-initiation phases of silencing. Indeed, the dynamic process by which nuclear RNAi engages a transcriptionally active target, before the repressive state is stably established, remains largely a mystery. Here we found that the onset of exo-dsRNA-induced nuclear RNAi is a transgenerational process, and that establishment requires SET-32, one of the three putative histone methyltransferases (HMTs) that are required for H3K9me3 deposition at the nuclear RNAi targets. We also performed multigenerational whole-genome analyses to examine the establishment of silencing at endogenous targets of germline nuclear RNAi. The nuclear Argonaute (AGO) protein HRDE-1 is essential for the maintenance of nuclear RNAi. Repairing a loss-of-function mutation in hrde-1 by CRISPR restored the silencing of endogenous targets in animals carrying wild type set-32. However, for numerous endogenous targets, repairing the hrde-1 mutation in a set-32;hrde-1 double mutant failed to restore their silencing states in up to 20 generations after the hrde-1 repair, using a similar genome editing approach. We found that despite a prominent role in the establishment of silencing, however, set-32 is completely dispensable for the maintenance of silencing once HRDE-1-dependent gene repression is established. Our study indicates that: 1) initiation and maintenance of siRNA-guided transcriptional repression are two distinct processes with different genetic requirements; and 2) the rate-limiting step of the establishment phase is a transgenerational, chromatin-based process. In addition, our study reveals a novel paradigm in which a heterochromatin factor primarily functions to promote the initiation of transgenerational silencing, expanding mechanistic understanding of the well-recognized role of heterochromatin in epigenetic maintenance.

Project description:Trans-generational epigenetic inheritance (TEI), which functionally intersects RNA with histone modification, recently forced a reinterpretation of the interplay between gene expression and selective pressures. Our groups integrate genetic, genomic, dynamic imaging, biochemistry and proteomic technologies to provide a functional mechanistic understanding of the interplay of TEI and the RNA interference (RNAi) phenomena in the nematode C. elegans. We discovered a family of proteins (the nuclear Argonaute-interacting proteins or NIPs), which controls the strength, inheritance and gene target specificity of nuclear RNAi. Loss of NIP-1 and NIP-2 in the soma leads to an enhancement of nuclear RNAi activities without affecting cytoplasmic RNAi. Loss of NIP-3 in the germline disables TEI and leads to a profoundly impaired response to transposable genomic elements (viral-like sequences). The genome of nip-3 mutants becomes de-stabilized; spontaneous visible mutations arise at high frequency due to an unbridled mobilization of a subset of transposable elements. Surprisingly, silencing of a distinct subset of transposable elements is coincidentally enhanced. Finally, expression imaging revealed an eminent role for the maturing male germline in TEI. This data supports a model wherein NIPs determine the potency and stability of TEI by gating and sorting small RNAs (which provide specificity) towards germline and somatic nuclear RNAi and epigenetic machineries. Our work further implies that this molecular machinery evolved to atone an animal’s epigenetic memory to preserve a species’ integrity in face of genetic pathogens.