In the nematode Caenorhabditis elegans, the terminal transferase RDE-3 adds a poly(UG)-tail to the free 3\' end of RNA molecules generated by the action of primary siRNAs or piRNAs. The tailed RNA serves as a template for RNA-dependent RNA polymerases (RdRp) to generate secondary siRNAs, thereby reinforcing the RNAi effect. In this iterative process, progressively shorter tailed RNAs are formed. In C. elegans, injection of poly(UG)-tailed single-stranded RNA (ssRNA) leads to RNAi-mediated gene silencing, thereby bypassing the need for the processing of double-stranded RNA into siRNAs. We wondered if poly(UG)-tailed ssRNAs could also be used for experimental gene knockdown in nematodes where long dsRNA-mediated RNAi does not work reliably, such as the satellite model organism Pristionchus pacificus or parasitic nematodes of the genus Strongyloides. Here we show that injection of poly(UG)-tailed RNA leads to gene knock down in P. pacificus and that the injected RNA, as well as the corresponding endogenous RNA, serve as substrate for the formation of new poly(UG)-tailed RNAs. Different from C. elegans, in P. pacificus, the knockdown effect depends on the redundant activity of the three rde-1 paralogs present in this species. We detected endogenously occurring poly(UG)-tailed RNAs derived from thousands of genes, more than half of which belong to germline-specific co-expression clusters. Mutations in Ppa-rde-3, lead to sterility. In contrast, in Strongyloides spp., we found poly(UG)-tailed RNAs to be much less abundant, if not absent. Our results show that poly(UG)-tailed RNAs are not restricted to C. elegans and suggest that they play an important function in the germ line in P. pacificus.