Centrosome duplication must be tightly regulated to maintain genomic stability. In Caenorhabditis elegans, the APC/C and co-activator FZR-1 function as negative regulators of centrosome duplication by targeting specific substrates for proteolytic degradation. While C. elegans SAS-5 and ZYG-1 have been identified as substrates of APC/CFZR-1, the mechanism by which APC/CFZR-1-dependent degradation influences centrosome assembly remains unclear. Here, we identified SPD-2, the conserved homolog of human CEP192, as an APC/CFZR-1 substrate. We show that loss of APC/CFZR-1 increases both cellular and centrosomal SPD-2 levels, and that SPD-2 physically associates with FZR-1 in vivo. Functional analyses of canonical D-box motifs reveal that D-box1, D-box2, and D-box3 each contribute to SPD-2 degradation, each with different functional consequences. Mutation of D-box3 alone partially rescued zyg-1 mutant phenotypes by restoring centrosome duplication and embryonic viability through increased centrosomal SPD-2 and ZYG-1. In contrast, mutating D-box1 or D-box2 elevated cellular SPD-2 but did not rescue zyg-1, with the D-box1 mutation further reducing centrosomal SPD-2 and exacerbating duplication defects and lethality in zyg-1 mutants. Our results reveal a conserved mechanism for APC/CFZR-1-dependent degradation of SPD-2 and indicate that SPD-2 stability is regulated by multiple D-box motifs, each associated with distinct functions, linking protein stability with centrosomal localization to ensure proper centrosome assembly during C. elegans embryogenesis.
Yim et al. (Wed,) studied this question.