AbstractGerm granules are biomolecular condensates that promote germ cell totipotency in most, if not all, animals. In C. elegans, MEG-3 and MEG-4 are two intrinsically disordered proteins that are redundantly required for the phase separations that drive germ granule assembly in germline blastomeres. Here, we show that animals lacking MEG-3/4 exhibit defects in dsRNA-mediated gene silencing (RNAi) that are due, at least in part, to defects in systemic RNAi. Interestingly, these RNAi defects are transgenerationally disconnected from meg-3/4 genotype: RNAi defects do not arise until 5-9 generations after animals become mutant for meg-3/4, and RNAi defects persist for 9-11 generations after meg-3/4 genotype is restored to wild type. Similar non-Mendelian patterns of inheritance are associated with other mutations that disrupt germ granule formation, indicating that germ granule disruption is the likely cause of genotype/phenotype disconnects. Loss of germ granules is associated with the production of aberrant populations of endogenous siRNAs, which, remarkably, are propagated for ≅10 generations in wild-type descendants of animals that lacked germ granules. sid-1, which encodes a factor required for systemic RNAi in C. elegans, is inappropriately and heritably silenced by aberrantly expressed sid-1 endogenous siRNAs, suggesting that transgenerational silencing of sid-1 likely underlies the heritable defect in RNAi. We conclude that one function of germ granules is to organize RNA-based epigenetic inheritance pathways and that failure to assemble germ granules has consequences that persist across many generations.
Charge pattern matching as a ‘fuzzy’ mode of molecular recognition for the functional phase separations of intrinsically disordered proteins
