Genetic analysis of Caenorhabditis elegans pry-1/Axin suppressors identifies genes involved in reproductive structure development, stress response, and aging
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ABSTRACTThe Axin family of scaffolding proteins regulates a wide array of developmental and post-developmental processes in eukaryotes. Studies in the nematode, Caenorhabditis elegans, have shown that the Axin homolog, PRY-1, plays essential roles in multiple tissues. To understand the genetic network of pry-1, we focused on a set of genes that are differentially expressed in the pry-1-mutant transcriptome and are linked to reproductive structure development. Eight of the genes (ard-1, rpn-7, cpz-1, his-7, cdk-1, rnr-1, clsp-1, and spp-1), when knocked down by RNA interference, efficiently suppressed the plate-level multivulva phenotype of pry-1 mutants. In every case, other than clsp-1 and spp-1, the ectopic vulval precursor cell (VPC) induction was also inhibited. The suppressor genes are members of known gene families in eukaryotes and perform essential functions. Our genetic interaction experiments revealed that except for clsp-1, the genes participate in one or more pry-1-mediated biological events. While four of them (cpz-1, his-7, cdk-1, and rnr-1) function in VPC induction, stress response, and aging, the other three (spp-1, ard-1, and rpn-7) are specific to one or more of these processes. Further analysis of the genes involved in aging showed that his-7, cdk-1, and rnr-1 also interacted with daf-16/FOXO. The results of genetic epistasis experiments suggested that his-7 functions upstream of daf-16, whereas cdk-1 and rnr-1 act downstream of the pry-1-daf-16 pathway. Altogether, these findings demonstrate the important role of pry-1 suppressors in C. elegans. Given that all of the genes described in this study are conserved, future investigations of their interactions with Axin and their functional specificity promises to uncover the genetic network of Axin under normal and disease states.
