Structural insights into mitotic-centrosome assembly

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Abstract

Centrosomal material assembles rapidly in mitosis. In Drosophila , the coiled-coil protein Cnn forms a scaffold that recruits PCM clients; in C.elegans , SPD-5 plays an analogous role. Here we show that full-length Cnn and SPD-5 can both form spherical condensates in vitro , but that the interactions driving their assembly into scaffolds inside cells appear to diverge. We show that the Cnn PReM adopts a helical hairpin fold that autoinhibits CM2 binding but that phosphorylation appears to increase hairpin breathing to permit CM2 engagement and robust scaffold assembly. Phospho-blocking mutations prevent PReM–CM2 interactions and scaffold formation, whereas phospho-mimetic substitutions partially restore function. The human homologue CDK5RAP2 contains a CM2 domain that can partially substitute for fly CM2 in vivo and we identify a candidate CDK5RAP2 PReM region that forms macromolecular networks with human CM2 in vitro . By contrast, the putative PReM and CM2 regions of SPD-5 cannot substitute for their equivalent fly domains and they do not interact detectably, suggesting a distinct assembly mechanism in worms despite conserved PLK1-dependent control of PCM growth.
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Abstract Centrosomal material assembles rapidly in mitosis. In Drosophila, the coiled-coil protein Cnn forms a scaffold that recruits PCM clients; in C.elegans, SPD-5 plays an analogous role. Here we show that full-length Cnn and SPD-5 can both form spherical condensates in vitro, but that the interactions driving their assembly into scaffolds inside cells appear to diverge. We show that the Cnn PReM adopts a helical hairpin fold that autoinhibits CM2 binding but that phosphorylation appears to increase hairpin breathing to permit CM2 engagement and robust scaffold assembly. Phospho-blocking mutations prevent PReM–CM2 interactions and scaffold formation, whereas phospho-mimetic substitutions partially restore function. The human homologue CDK5RAP2 contains a CM2 domain that can partially substitute for fly CM2 in vivo and we identify a candidate CDK5RAP2 PReM region that forms macromolecular networks with human CM2 in vitro. By contrast, the putative PReM and CM2 regions of SPD-5 cannot substitute for their equivalent fly domains and they do not interact detectably, suggesting a distinct assembly mechanism in worms despite conserved PLK1-dependent control of PCM growth. Competing Interest Statement The authors have declared no competing interest. Footnotes Edited Figures with glitches in visualization

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last seen: 2026-05-20T01:45:00.602351+00:00