Project description:Epigenetic modifications that arise during plant and animal development, such as DNA and histone modification, are mostly reset during gamete formation, but some are inherited from the germline including those marking imprinted genes. Small RNAs guide these epigenetic modifications, and some are also inherited by the next generation. In C. elegans, these inherited small RNAs have poly (UG) tails, but how inherited small RNAs are distinguished in other animals and plants is unknown. Pseudouridine (Ψ) is the most abundant RNA modification but has not been explored in small RNAs. Here, we developed novel assays to detect Ψ in short RNA sequences, demonstrating its presence in mouse and Arabidopsis microRNAs and their precursors. We also detected substantial enrichment in germline small RNAs, namely epigenetically activated siRNAs (easiRNAs) in Arabidopsis pollen, and PIWI-interacting piRNAs in mouse testis. In pollen, pseudouridylated easiRNAs are produced by RNA polymerase IV and localized to sperm cells. We found that PAUSED/HEN5 (PSD), the plant homolog of Exportin-t, interacts genetically with Ψ synthase and is required for transport of easiRNAs into sperm cells from the vegetative nucleus. We further show that PSD is required for the triploid block: chromosome dosage-dependent seed lethality that is epigenetically inherited from pollen. We propose that Ψ has a conserved role in marking inherited small RNAs in the germline.

Project description:Pseudouridine (Ψ) is an isomer of uridine found in ribosomal, transfer and other structural RNAs as well as in some mRNAs and non-coding RNAs, but is difficult to detect in short RNA sequences. Using modified techniques we found Ψ in microRNAs (miRNAs) and their precursors from mammalian and plant cells, primarily at the 5ʹ terminus of the mature miRNA. Small RNAs targeting transposons in reproductive cells (piRNA in testis and easiRNA in pollen) were highly enriched for Ψ, indicating a potential role in epigenetic inheritance. In pollen, pseudouridylated small RNAs were produced by RNA polymerase IV and were localized to sperm cells, as were miRNAs with terminal Ψ. We show that pseudouridylated easiRNAs from pollen contribute to imprinting and the triploid block (chromosome dosage-dependent epigenetic lethality) via the activity of PAUSED/HEN5, the plant homolog of Exportin-t. Exportin-t is required for nuclear export of pseudouridylated tRNA, and we found that PSD is required for cell-cell transport of small RNA in the germline.

Project description:It is unknown whether the activity of the nervous system can be inherited. In Caenorhabditis elegans nematodes, parental responses can transmit heritable small RNAs that regulate gene expression transgenerationally. In this study we show that a neuronal process can impact the next generations. Neurons-specific synthesis of RDE-4-dependent small RNAs regulates germline amplified endogenous siRNAs and germline gene expression for multiple generations. Further, the production of small RNAs in neurons controls the chemotaxis behavior of the progeny for at least three generations via the germline Argonaute HRDE-1. Among the targets of these small RNAs we identified the conserved gene saeg-2, which is transgenerationally downregulated in the germline. Silencing of saeg-2 following neuronal small RNA biogenesis is required for chemotaxis under stress. Thus, we propose a small RNA-based mechanism for communication of neuronal processes transgenerationally.

Project description:Epigenetic inheritance of acquired traits is widespread among eukaryotes but how and to what extent such information is trans-generationally inherited is still unclear. The patterns of programmed DNA elimination in ciliates are epigenetically and trans-generationally inherited, and it has been proposed that small RNAs, which shuttle between the germline and the soma, regulate this epigenetic inheritance. In this study, we test the existence of such small RNA-mediated communication by epigenetically disturbing the pattern of DNA elimination in Tetrahymena. We show that the pattern of DNA elimination is indeed determined by the selective turnover of small RNAs, which is induced by the interaction between germline-derived small RNAs and the somatic genome. In addition, we show that DNA elimination of an element is regulated by small RNA-mediated communication with other eliminated elements. By contrast, no evidence obtained thus far supports the notion that transfer of epigenetic information from the soma to the germline, if any, regulates DNA elimination. Our results indicate that small RNA-mediated trans-nuclear and trans-element communication, in addition to unknown information in the germline genome, contributes to determining the pattern of DNA elimination.

Project description:Zebrafish germline small RNAs

Project description:RNA-seq transcriptome analysis of C. elegans germlines that inherited only paternal chromosomes (non-Mendelian inheritance, 'red-head worms') and the germlines of their offspring ('offspring of red-head worms') vs. germlines that inherited both maternal and paternal chromosomes (Mendelian inheritance, HBR1280 control). Given that epigenetic marking of sperm chromosomes is faithfully transmitted through embryo cell divisions, and that sperm epigenetic marking is important in offspring, we tested if sperm epigenetic marking alone is sufficient for proper development of the germline in offspring. We utilized a mutant that, during the first embryonic division, delivers the sperm genome to the daughter cell that generates the germline and the oocyte genome to the other daughter cell (Besseling & Bringmann, 2016). This mutant over-expresses GPR-1, a protein involved in regulation of kinetochore pulling forces. GPR-1 over-expression results in excessive pulling forces, causing the paternal and maternal pronuclei to inappropriately move to opposite poles of the 1-cell embryo instead of merging in the center of the embryo. In this mutant background, ~60% of offspring undergo atypical chromosome segregation, generating mosaic embryos whose germlines are derived entirely from sperm chromosomes (Besseling & Bringmann, 2016). To track the parental genomes, differentially tagged histone transgenes were used: a GFP-tagged histone H2B encoded in the sperm genome, and a TdTomato-tagged histone H2B encoded in the oocyte genome. The mosaic embryos whose germline inherited only sperm chromosomes (‘red-head' worms) develop into fertile adults with a normal brood size, similar to control worms, in which the germline inherited both sperm and oocyte chromosomes. RNA-seq analysis demonstrated that the germline transcriptome of ‘red-head’ worms and their offspring show few (<80 genes) and minor changes compared to control worms. These findings demonstrate that epigenetic information provided by sperm can guide proper germ cell development.

Project description:The mutagenic activity of transposable elements (TEs) is suppressed by epigenetic silencing and small interfering RNAs (siRNAs), especially in gametes that would transmit transposed elements to the next generation. In pollen from the model plant Arabidopsis, we show that TEs are unexpectedly reactivated and transpose, but only in the pollen vegetative nucleus, which accompanies the sperm cells but does not provide DNA to the fertilized zygote. TE expression coincides with down-regulation of the heterochromatin remodeler DECREASE IN DNA METHYLATION 1 and of most TE siRNAs. However, 21 nucleotide siRNA from Athila retrotransposons is generated in pollen and accumulates in sperm, indicating that siRNA from TEs activated in the vegetative nucleus can target silencing in gametes. We propose a conserved role for reprogramming in germline companion cells, such as nurse cells in insects and vegetative nuclei in plants, to reveal intact TEs in the genome and regulate their activity in gametes. Mature pollen was collected from Columbia reference strain plants by vacuum filtration (Johnson-Brousseau and McCormick, 2004). DNA and RNA were isolated from a ddm1-2 plant in the Columbia reference background. Small RNAs of 19–28 nt were size selected by denaturing 15% PAGE, and cloned as in Brennecke et al. (2007). Additional details regarding the cloning of small RNAs are found in the Supplemental Data. The small RNA libraries were sequenced on Illumina 1G sequencer. The total number of sequences perfectly matching the Arabidopsis genome were as follows: WT inflorescence, 4,158,848 (2,286,133 unique); WT pollen, 1,034,665 (437,984 unique); ddm1 inflorescence, 4,098,772 (1,637,771 unique); and WT sperm, 760,651 (429,972 unique).

Project description:Small noncoding RNAs in tomato pollen

Project description:PIWI-interacting RNAs (piRNAs), a class of small RNAs that guide transposon silencing in animals, are processed in the cytoplasm from RNA Polymerase II transcripts. How piRNA precursors, which often lack RNA maturation signatures and thereby violate quality control checkpoints, achieve nuclear export is unknown. Here, we uncover a germline-specific RNA export pathway in Drosophila, that escorts piRNA precursors from their heterochromatic origins to nuage, the cytoplasmic piRNA processing centres. This pathway connects canonical nuclear export factors—the RNA helicase UAP56, the NXF cofactor Nxt1/p15, and the exportin Crm1/Xpo1—with Nxf3, a variant of the mRNA exporter Nxf1/Tap. Nxf3 recruitment to nascent piRNA precursors occurs via the heterochromatin protein 1-variant Rhino and CG13741/Bootlegger, a new piRNA pathway factor, thereby making piRNA precursor export independent of RNA processing events. Thus, similar to retroviral hijacking of cellular export factors, piRNA precursor export evolved to bend canonical gene expression rules through bypassing nuclear RNA surveillance mechanisms.

Project description:Germline Argonautes direct transcriptome surveillance within peri-nuclear membraneless organelles called nuage. In C. elegans, a family of Vasa-related Germ Line Helicase (GLH) proteins localize in, and promote the formation of nuage called P granules. Previous studies have implicated GLH proteins in inherited silencing but direct roles in amplification of small RNAs, or in target mRNA or Argonatue binding have not been identified. Here we show that GLH proteins compete with each other to control Argonaute pathway specificity, bind directly to Argonaute-target mRNAs and act to promote the amplification of small RNAs required for transgenerational inheritance. We show that the ATPase cycle of GLH-1 regulates its direct binding to the Argonaute WAGO-1 which engages amplified small RNAs. Our findings support a dynamic and direct role for GLH proteins in inherited silencing beyond their role as structural components of nuage.