Project description:Transposable elements (TEs) are genomic parasite that threat genome integrity. One major strategy organisms evolved to balance TE activity in the germline is the Piwi-interacting RNAs (piRNAs) pathway. It prevents transposition by repressing TE at transcriptional and/or post-transcriptional level. However, evidence that TE derepression caused by piRNA pathway impairment is actually followed by bursts of transposition is still lacking. Here we present a genome-wide TE-analyses of the replicative TE life cycle (their expression, their translation to their transposition in the germline) after piRNA pathway impairment in the somatic follicle cells. We observed a high transposition-rate in the germline, leading to a 10-fold increase in genomic TE-load after 70 successive generations of piRNA pathway impairment. Moreover, we demonstrate that siRNAs co-regulate TE activity at post transcriptional level in follicle cells. These observations demonstrate that the small RNA-mediated TE repression in follicle cells contribute to genome homeostasis.

Project description:Transposable elements (TEs) are genomic parasite that threat genome integrity. One major strategy organisms evolved to balance TE activity in the germline is the Piwi-interacting RNAs (piRNAs) pathway. It prevents transposition by repressing TE at transcriptional and/or post-transcriptional level. However, evidence that TE derepression caused by piRNA pathway impairment is actually followed by bursts of transposition is still lacking. Here we present a genome-wide TE-analyses of the replicative TE life cycle (their expression, their translation to their transposition in the germline) after piRNA pathway impairment in the somatic follicle cells. We observed a high transposition-rate in the germline, leading to a 10-fold increase in genomic TE-load after 70 successive generations of piRNA pathway impairment. Moreover, we demonstrate that siRNAs co-regulate TE activity at post transcriptional level in follicle cells. These observations demonstrate that the small RNA-mediated TE repression in follicle cells contribute to genome homeostasis.

Project description:Transposable elements (TEs) are genomic parasite that threat genome integrity. One major strategy organisms evolved to balance TE activity in the germline is the Piwi-interacting RNAs (piRNAs) pathway. It prevents transposition by repressing TE at transcriptional and/or post-transcriptional level. However, evidence that TE derepression caused by piRNA pathway impairment is actually followed by bursts of transposition is still lacking. Here we present a genome-wide TE-analyses of the replicative TE life cycle (their expression, their translation to their transposition in the germline) after piRNA pathway impairment in the somatic follicle cells. We observed a high transposition-rate in the germline, leading to a 10-fold increase in genomic TE-load after 70 successive generations of piRNA pathway impairment. Moreover, we demonstrate that siRNAs co-regulate TE activity at post transcriptional level in follicle cells. These observations demonstrate that the small RNA-mediated TE repression in follicle cells contribute to genome homeostasis.

Project description:Somatic piRNA pathway prevents transgenerational germline transposition

Project description:Somatic piRNA pathway prevents transgenerational germline transposition [smallRNA-seq]

Project description:Somatic piRNA pathway prevents transgenerational germline transposition [DNA-seq]

Project description:Somatic piRNA pathway prevents transgenerational germline transposition [RNA-seq]

Project description:Somatic piRNA pathway prevents transgenerational germline transposition [circularDNA-seq]

Project description:In mammals, the acquisition of the germline from the soma provides the germline with an essential challenge, the necessity to erase and reset genomic methylation. In the male germline RNA-directed DNA methylation silences young active transposable elements (TEs). The PIWI protein MIWI2 (PIWIL4) and its associated PIWI-interacting RNAs (piRNAs) are proposed to tether MIWI2 to nascent TE transcripts and instruct DNA methylation. The mechanism by which MIWI2 directs de novo TE methylation is poorly understood but central to the immortality of the germline. Here, we define the interactome of MIWI2 in foetal gonocytes that are undergoing de novo genome methylation and identify a novel MIWI2-associated factor, SPOCD1, that is essential for young TE methylation and silencing. The loss of Spocd1 in mice results in male specific infertility and does not impact on piRNA biogenesis nor localization of MIWI2 to the nucleus. SPOCD1 is a nuclear protein and its expression is restricted to the period of de novo genome methylation. We found SPOCD1 co-purified in vivo with DNMT3L and DNMT3A, components of the de novo methylation machinery as well as constituents of the NURD and BAF chromatin remodelling complexes. We propose a model whereby tethering of MIWI2 to a nascent TE transcript recruits repressive chromatin remodelling activities and the de novo methylation apparatus through its association with SPOCD1. In summary, we have identified a novel and essential executor of mammalian piRNA-directed DNA methylation.

Project description:Transposable elements (TEs) are mobile sequences that engender widespread mutations and thus are a major hazard that must be silenced. The most abundant active class of TEs in mammalian genomes is long interspersed element class 1 (LINE1). Here, we report that LINE1 transposition is suppressed in the male germline by transcription factors encoded by a rapidly evolving X-linked homeobox gene cluster. LINE1 transposition is repressed by many members of this RHOX transcription factor family, including those with different patterns of expression during spermatogenesis. One family member—RHOX10—suppresses LINE1 transposition during fetal development in vivo when the germline would otherwise be susceptible to LINE1 activation because of epigenetic reprogramming. We provide evidence that RHOX10 suppresses LINE transposition by inducing Piwil2, which encodes a key component in the Piwi-interacting (pi) RNA pathway that protects against TEs. The ability of RHOX transcription factors to suppress LINE1 is conserved in humans, but is lost in RHOXF2 mutants from several infertile human patients, raising the possibility that loss of RHOXF2 causes human infertility by allowing uncontrolled LINE1 expression in the germline. Together, our results support a model in which the Rhox gene cluster is in an evolutionary arms race with TEs, resulting in expansion of the Rhox gene cluster to suppress TEs in different biological contexts.