Members of the Argonaute family of proteins, which interact with small RNAs, are the key players of RNAi and other related pathways. The C. elegans genome encodes 27 members of the Argonaute family. During this thesis research, we sought to understand the functions of the members of this gene family in C. elegans. Among the Argonaute family members, rde-1 and alg-1/2have previously been shown to be essential for RNAi and development, respectively. In this work, we wanted to assign functions to the remaining members of this large family of proteins. Here, we describe the phenotype of 31 deletion alleles representing all of the previously uncharacterized Argonaute members. In addition to rde-1, our analysis revealed that two other Argonaute members csr-1 and prg-1 are also essential for development. csr-1 is partially required for RNAi, and essential for proper chromosome segregation. prg-1, a member of PIWI subfamily of Argonaute genes, exhibits reduced brood size and temperature-sensitive sterile phenotype, implicating that it is required for germline maintenance. Additionally, we showed that RDE-1 interacts with trigger-derived sense and antisense siRNAs (primary siRNAs) to initiate RNAi, while several other Argonaute proteins, SAGO-1, SAGO-2, and perhaps others, functioning redundantly, interact with amplified siRNAs (secondary siRNAs) to mediate downstream silencing. Moreover, our analysis uncovered that another member of Argonaute gene family, ergo-1, is essential for the endogenous RNAi pathway. Furthermore, we built an eight-fold Argonaute mutant, MAGO8, and analyzed its developmental phenotype and sensitivity to RNAi. Our analysis revealed that the genes deleted in the MAGO8 mutant function redundantly with each other, and are required for RNAi and the maintenance of the stem cell totipotency.

Argonaute (AGO) proteins interact with small RNAs to mediate gene silencing. C. elegans contains 27 AGO genes, raising the question of what roles these genes play in RNAi and related gene-silencing pathways. Here we describe 31 deletion alleles representing all of the previously uncharacterized AGO genes. Analysis of single- and multiple-AGO mutant strains reveals functions in several pathways, including (1) chromosome segregation, (2) fertility, and (3) at least two separate steps in the RNAi pathway. We show that RDE-1 interacts with trigger-derived sense and antisense RNAs to initiate RNAi, while several other AGO proteins interact with amplified siRNAs to mediate downstream silencing. Overexpression of downstream AGOs enhances silencing, suggesting that these proteins are limiting for RNAi. Interestingly, these AGO proteins lack key residues required for mRNA cleavage. Our findings support a two-step model for RNAi, in which functionally and structurally distinct AGOs act sequentially to direct gene silencing.