Project description:The centrosome is the master orchestrator of mitotic spindle formation and chromosome segregation in animal cells. Centrosome abnormalities are frequently observed in cancer, but little is known of their origin and about pathways affecting centrosome homeostasis. Here we show that autophagy preserves centrosome organization and stability through selective turnover of centriolar satellite components, a process we termed doryphagy. Autophagy targets the satellite organizer PCM1 by interacting with GABARAPs via a C-terminal LIR motif. Accordingly, autophagy deficiency results in accumulation of large abnormal centriolar satellites and a resultant dysregulation of centrosome composition. These alterations have critical impact on centrosome stability and lead to mitotic centrosome fragmentation and unbalanced chromosome segregation. Our findings identify doryphagy as an important centrosome-regulating pathway and bring mechanistic insights to the link between autophagy dysfunction and chromosomal instability. In addition, we highlight the vital role of centriolar satellites in maintaining centrosome integrity.

Project description:Centriolar satellites are an array of membrane-less granules that localize and move around the vertebrate centrosome/cilium complex. They have recently emerged as key regulators of the biogenesis and function of the centrosome/cilium-complex and their mutations are linked to ciliopathies. Although centriolar satellites are ubiquitous structures of the vertebrate cells, their precise function and molecular mechanism of action in different cell types remain poorly understood. Here, we generated kidney and retinal epithelial cells that lack centriolar satellites by genetically ablating their scaffolding protein PCM1 and investigated the cellular and molecular consequences of satellite loss in cells. We showed that centriolar satellites are required for cilium assembly, regulation of ciliary content, timely response to Hedgehog signals and three- dimensional epithelial cell organization, but not for cell proliferation, cell cycle progression and centriole duplication. Importantly, the requirement for centriolar satellites in cilium assembly varied between retinal and kidney epithelial cells and we identified the differences in the efficiency of targeting key ciliogenesis factors to the centrosome including Mib1 and Talpid3 as the likely molecular basis for this phenotypic variability. Quantitative global transcriptomic and proteomic profiling of satellite-less cells showed that loss of centriolar satellites does not lead to a major transcriptional response, but leads to a significant rearrangement of the global proteome. Together, our findings identify important roles for centriolar satellites in key cilium-related cellular processes through regulating the proteostasis and centrosomal/ciliary targeting of proteins and provide insight into the disease mechanisms of ciliopathies.

Project description:Excess centrosomes cause defects in mitosis, cell-signaling, and cell migration, and therefore their assembly is tightly regulated. The divergent Polo kinase, PLK4, controls centriole duplication at the heart of centrosome assembly, and elevated PLK4 levels promote centrosome amplification (CA), a founding event of tumorigenesis. Here, we investigate the transcriptional consequences of elevated PLK4 and find Unkempt (UNK), a gene encoding an RNA binding protein with roles in mRNA translational regulation, to be one of only two upregulated mRNAs. UNK protein localizes to centrosomes and CEP131-positive centriolar satellites and promotes CEP131 localization to and around centrosomes. UNK's RNA binding activity is required for PLK4-induced centriole overduplication. Consistent with the loss in PLK4-induced centriole overduplication, UNK depletion disrupts PLK4 and centriole assembly protein localization. Finally, translation is enriched at centrosomes and centriolar satellites with UNK and CEP131 promoting this localized translation. In summary, UNK and CEP131 promote PLK4 localization and local translation at centrosomes during centriole overduplication.

Project description:Proper centrosome movement to the bipolar position is a prerequisite for bipolar spindle orientation and genome stability. Polo like kinase 1 (Plk1) is a key mitotic kinase which controls centrosome separation. Here we found that Plk1 phosphorylated residue Thr76 in VCP/p97, an AAA-ATPase mainly involved in protein homeostasis, at centrosome from prophase to anaphase. This phosphorylation recruited VCP to centrosome to regulate centrosome orientation. VCP also exhibited strong co-localization with Eg5, a mitotic kinesin motor for centrosome movement, at mitotic spindle, and dephosphorylation of Thr76 in VCP was required for the enrichment of VCP and Eg5 to the spindle, thus, ensuring proper spindle orientation and chromosome segregation. Since genome instability is the hallmark of cancer and the phosphorylation of Thr76 in VCP is important for proper centrosome movement, spindle orientation, and chromosome segregation, we, thus, knocked down VCP in MDA-MB-231cells by its specific shRNA, and reconstituted the expression of VCP by infecting the cells with lentivirus encoding shRNA-resistant Flag-VCPWT or Flag-VCPT76A. We then implanted VCPWT- or VCPT76A-expressing MDA-MB-231 cells into nude mice and found that the tumor growth in mice implanted with VCPT76A-expressing cells was significantly slower when compared with the mice implanted with the Flag-VCPWT-expressing cells. To better understand the decreased tumor formation ability of Flag-VCPT76A-expressing cells, we isolated the primary breast tumor tissues for the RNA-Seq analysis. Of the 57,905 mapped whole genome genes in the isolated tumors, we identified 234 differentially expressed genes (DEGs; false discovery rate (FDR) < 0.1).

Project description:Centriolar satellites are multiprotein aggregates that orbit the centrosome and govern centrosome homeostasis and primary cilia formation. In contrast to the scaffold PCM1, which nucleates centriolar satellites and has been linked to microtubule dynamics, autophagy, and intracellular trafficking, the functions of its close interactant CEP131 beyond ciliogenesis remain unclear. By using a knockout strategy in a T-cell line unable to form primary cilia, we report that, although dispensable for centriolar satellite assembly, CEP131 participates in optimal tubulin modifications and microtubule regrowth. Our unsupervised label-free proteomic analysis by quantitative mass spectrometry further uncovered both a mitochondrial and an anti-apoptotic signature. Without CEP131, mitochondria showed increased respiration and formed a more elongated network. In response to cell death inducers converging on mitochondria, knockout cells displayed delayed cytochrome c release from mitochondria, subsequent caspases activation, and ultimately in apoptosis. This defect in mitochondrial permeabilization was intrinsic as it could be recapitulated in vitro with isolated organelles. Together, these data extend the functions of CEP131 to life-and-death decisions and propose ways to interfere with mitochondrial apoptosis.

Project description:Bipolar spindle assembly and chromosome biorientation are prerequisites for chromosome segregation during cell division. The kinesin motor KIF11 (also widely known as Eg5) drives spindle bipolarization by sliding antiparallel microtubules bidirectionally, elongating a spherical spindle into a bipolar-shaped structure in acentrosomal oocytes. During meiosis I, this process stretches homologous chromosome pairs, establishing chromosome biorientation at the spindle equator. The quantitative requirement for KIF11 in acentrosomal spindle bipolarization and homologous chromosome biorientation remains unclear. Here, using a genetic strategy to modulate KIF11 expression levels, we show that Kif11 haploinsufficiency impairs spindle elongation, leading to the formation of a partially bipolarized spindle during meiosis I in mouse oocytes. While the partially bipolarized spindle allows chromosome stretching in the inner region of its equator, it fails to do so in the outer region, where merotelic kinetochore-microtubule attachments are favored to form. These findings demonstrate the necessity of biallelic functional Kif11 for bipolar spindle assembly in acentrosomal oocytes and reveal a spatially differential requirement for homologous chromosome biorientation within the spindle.

Project description:Kinetochores are multiprotein assemblies that bind chromosomes to the spindle during mitosis. Despite conserved roles, repertoires of kinetochore proteins vary greatly across eukaryotes. In particular, most known components are not clearly detected in a group of parasites known as the Apicomplexa. Furthermore, flexibility in scale of amplification and an apparent incapability to delay cell cycle progression in response to spindle integrity has coined an idea these parasites divide in the absence of spindle checkpoints. In this study, we reunite divergent apicomplexan kinetochore components to a common eukaryotic set and additionally identify 9 kinetochore proteins that share little homology to known proteins. AKiTs are essential for chromosome segregation and show modes of division parallel to eukaryotic metaphase to anaphase transition and spindle assembly checkpoint signaling. These findings suggest conserved spindle assembly checkpoint signaling maintains fidelity during chromosome segregation in apicomplexan parasites.

Project description:Condensin complexes are highly conserved for chromosome compaction to ensure their faithful segregation in mitosis. However, little is known about the role of condensin complexes in interphase. Condensins exists in two complexes, condensins I and II, in higher eukayotic cells. During interphase, condensin II is predominantly localized in the nucleus throughout the cell cycle, whereas condensin I is localized at the cytoplasm in interphase. The distinct localization patterns suggest that condensin II, but not condensin I, may contribute to genome organization in interphase. Our results suggest that condensin II is associated with TFIIIC complex in humans.

Project description:Chromatin fibres dynamically change their organisation during cell cycle. In interphase nucleus, chromatin fibres are evenly distributed whereas their spatial occupancy are reorganised to form condensed chromosomes in mitosis. This process called chromosome condensation is necessary for an accomplishment of faithful chromosome segregation. One of the Structural Maintenance of Chromosomes complexes, Condensin, is indispensable for chromosome condensation. It remains, however, unknown how Condensin plays its role in shaping mitotic chromosome. Here we show that chromatin fibres change their interacting partners; short-range contacts in interphase nucleus are converted into long-range interactions to shape condensed chromosomes. This conversion of interactions among chromatin fibres results in the formation of larger domains within mitotic chromosomes. Condensin is solely in charge of the conversion and large domain formation in fission yeast mitosis. Our results show how fission yeast Condensin is involved in shaping mitotic chromosomes.

Project description:Chromatin fibres dynamically change their organisation during cell cycle. In interphase nucleus, chromatin fibres are evenly distributed whereas their spatial occupancy are reorganised to form condensed chromosomes in mitosis. This process called chromosome condensation is necessary for an accomplishment of faithful chromosome segregation. One of the Structural Maintenance of Chromosomes complexes, Condensin, is indispensable for chromosome condensation. It remains, however, unknown how Condensin plays its role in shaping mitotic chromosome. Here we show that chromatin fibres change their interacting partners; short-range contacts in interphase nucleus are converted into long-range interactions to shape condensed chromosomes. This conversion of interactions among chromatin fibres results in the formation of larger domains within mitotic chromosomes. Condensin is solely in charge of the conversion and large domain formation in fission yeast mitosis. Our results show how fission yeast Condensin is involved in shaping mitotic chromosomes.