Centrosomes are microtubule-organizing centres of animal cells. They influence the morphology of the microtubule cytoskeleton, function as the base for the primary cilium and serve as a nexus for ...important signalling pathways. At the core of a typical centrosome are two cylindrical microtubule-based structures termed centrioles, which recruit a matrix of associated pericentriolar material. Cells begin the cell cycle with exactly one centrosome, and the duplication of centrioles is constrained such that it occurs only once per cell cycle and at a specific site in the cell. As a result of this duplication mechanism, the two centrioles differ in age and maturity, and thus have different functions; for example, the older of the two centrioles can initiate the formation of a ciliary axoneme. We discuss spatial aspects of the centrosome duplication cycle, the mechanism of centriole assembly and the possible consequences of the inherent asymmetry of centrioles and centrosomes.
Centrioles are microtubule-based core components of centrosomes and cilia. They are duplicated exactly once during S-phase progression. Central to formation of each new (daughter) centriole is the ...formation of a nine-fold symmetrical cartwheel structure onto which microtubule triplets are deposited. In recent years, a module comprising the protein kinase polo-like kinase 4 (PLK4) and the two proteins STIL and SAS-6 have been shown to stay at the core of centriole duplication. Depletion of any one of these three proteins blocks centriole duplication and, conversely, overexpression causes centriole amplification. In this short review article, we summarize recent insights into how PLK4, STIL and SAS-6 co-operate in space and time to form a new centriole. These advances begin to shed light on the very first steps of centriole biogenesis.
Centrioles are conserved microtubule-based organelles that form the core of the centrosome and act as templates for the formation of cilia and flagella. Centrioles have important roles in most ...microtubule-related processes, including motility, cell division and cell signalling. To coordinate these diverse cellular processes, centriole number must be tightly controlled. In cycling cells, one new centriole is formed next to each pre-existing centriole in every cell cycle. Advances in imaging, proteomics, structural biology and genome editing have revealed new insights into centriole biogenesis, how centriole numbers are controlled and how alterations in these processes contribute to diseases such as cancer and neurodevelopmental disorders. Moreover, recent work has uncovered the existence of surveillance pathways that limit the proliferation of cells with numerical centriole aberrations. Owing to this progress, we now have a better understanding of the molecular mechanisms governing centriole biogenesis, opening up new possibilities for targeting these pathways in the context of human disease.
The Ska complex is an essential mitotic component required for accurate cell division in human cells. It is composed of three subunits that function together to establish stable ...kinetochore-microtubule interactions in concert with the Ndc80 network. We show that the structure of the Ska core complex is a W-shaped dimer of coiled coils, formed by intertwined interactions between Ska1, Ska2, and Ska3. The C-terminal domains of Ska1 and Ska3 protrude at each end of the homodimer, bind microtubules in vitro when connected to the central core, and are essential in vivo. Mutations disrupting the central coiled coil or the dimerization interface result in chromosome congression failure followed by cell death. The Ska complex is thus endowed with bipartite and cooperative tubulin-binding properties at the ends of a 350 Å-long molecule. We discuss how this symmetric architecture might complement and stabilize the Ndc80-microtubule attachments with analogies to the yeast Dam1/DASH complex.
▸ Ska1, Ska2, and Ska3 N termini form a coiled coil and dimerize into a W-shaped core ▸ The coiled coil and dimerization interface are essential for Ska function in vivo ▸ Ska1 and Ska3 C termini extend symmetrically on both sides of the W-shaped core ▸ Ska1 and Ska3 C termini are essential and bind microtubules when linked to the core
STIL is a centriole duplication factor that localizes to the procentriolar cartwheel region, and mutations in STIL are associated with autosomal recessive primary microcephaly (MCPH). Excess STIL ...triggers centriole amplification, raising the question of how STIL levels are regulated.
Using fluorescence time-lapse imaging, we identified a two-step process that culminates in the elimination of STIL at the end of mitosis. First, at nuclear envelope breakdown, Cdk1 triggers the translocation of STIL from centrosomes to the cytoplasm. Subsequently, the cytoplasmic bulk of STIL is degraded via the anaphase-promoting complex/cyclosome (APC/C)-proteasome pathway. We identify a C-terminal KEN box as critical for STIL degradation. Remarkably, this KEN box is deleted in MCPH mutants of STIL, rendering STIL resistant to proteasomal degradation and causing centriole amplification.
Our results reveal a role for Cdk1 in STIL dissociation from centrosomes during early mitosis, with implications for the timing of cartwheel disassembly. Additionally, we propose that centriole amplification triggered by STIL stabilization is the underlying cause of microcephaly in human patients with corresponding STIL mutations.
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•Cdk1 triggers dissociation of STIL from early mitotic centrosomes•A KEN box is critical for APC/C-mediated degradation of STIL at mitotic exit•The KEN box is deleted in STIL truncations from primary microcephaly patients•Microcephaly may result from STIL stabilization and centriole amplification
Arquint and Nigg have studied the regulation of STIL, a centriole duplication factor implicated in microcephaly, and have discovered a two-step process that triggers STIL degradation in late mitosis. In microcephaly patients, a critical KEN box is deleted, resulting in STIL stabilization and centriole amplification.
Primary cilia play critical roles in development and disease. Their assembly is triggered by mature centrioles (basal bodies) and requires centrosomal protein 164kDa (Cep164), a component of distal ...appendages. Here we show that loss of Cep164 leads to early defects in ciliogenesis, reminiscent of the phenotypic consequences of mutations in TTBK2 (Tau tubulin kinase 2). We identify Cep164 as a likely physiological substrate of TTBK2 and demonstrate that Cep164 and TTBK2 form a complex. We map the interaction domains and demonstrate that complex formation is crucial for the recruitment of TTBK2 to basal bodies. Remarkably, ciliogenesis can be restored in Cep164-depleted cells by expression of chimeric proteins in which TTBK2 is fused to the C-terminal centriole-targeting domain of Cep164. These findings indicate that one of the major functions of Cep164 in ciliogenesis is to recruit active TTBK2 to centrioles. Once positioned, TTBK2 then triggers key events required for ciliogenesis, including removal of CP110 and recruitment of intraflagellar transport proteins. In addition, our data suggest that TTBK2 also acts upstream of Cep164, contributing to the assembly of distal appendages.
Intraflagellar transport (IFT) of ciliary precursors such as tubulin from the cytoplasm to the ciliary tip is involved in the construction of the cilium, a hairlike organelle found on most eukaryotic ...cells. However, the molecular mechanisms of IFT are poorly understood. Here, we found that the two core IFT proteins IFT74 and IFT81 form a tubulin-binding module and mapped the interaction to a calponin homology domain of IFT81 and a highly basic domain in IFT74. Knockdown of IFT81 and rescue experiments with point mutants showed that tubulin binding by IFT81 was required for ciliogenesis in human cells.
Centrioles are barrel-shaped structures that are essential for the formation of centrosomes, cilia, and flagella. Here we review recent advances in our understanding of the function and biogenesis of ...these organelles, and we emphasize their connection to human disease. Deregulation of centrosome numbers has long been proposed to contribute to genome instability and tumor formation, whereas mutations in centrosomal proteins have recently been genetically linked to microcephaly and dwarfism. Finally, structural or functional centriole aberrations contribute to ciliopathies, a variety of complex diseases that stem from the absence or dysfunction of cilia.
Mitosis and cytokinesis are undoubtedly the most spectacular parts of the cell cycle. Errors in the choreography of these processes can lead to aneuploidy or genetic instability, fostering cell death ...or disease. Here, I give an overview of the many mitotic kinases that regulate cell division and the fidelity of chromosome transmission.