Cleavage of cohesin rings coordinates the separation of centrioles and chromatids

Schöckel, Laura; Möckel, Martin M.; Mayer, Bernd; Boos, Dominik; Stemmann, Olaf

doi:10.1038/ncb2280

Cited by 158 publications

(146 citation statements)

References 40 publications

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“…Inhibition of Plk1 in a Xenopus CSF extract, for example, will block disengagement in the presence of separase (Schockel et al 2011), and overexpression of Plk1 will promote centriole disengagement in G 2 (Loncarek et al 2010). It also seems that APC/C activity contributes to disengagement (Prosser et al 2012), and that Plk1 and APC/ C-Cdh1 activities can independently achieve this (Hatano and Sluder 2012).…”

Section: The Centrosome and Its Duplication Cyclementioning

confidence: 99%

“…Although the notion that centriole disengagement and chromatid separation might share common machinery appears elegant, whether cohesin is a separase substrate in both processes remains confusing. Although one study has reported that a noncleavable cohesin subunit Scc1 would not prevent disengagement in HeLa cells (Tsou et al 2009), another suggested otherwise in Hek293 cells (Schockel et al 2011). If endogenous Scc1 was replaced by a variant carrying a recognition site for human rhinovirus HRV protease or if its partner protein, Smc3, carried a site for TEV protease, these molecules could be cleaved by the appropriate protease resulting in centriole disengagement.…”

Section: The Centrosome and Its Duplication Cyclementioning

confidence: 99%

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The Centrosome and Its Duplication Cycle

Hagan

Glover

2015

Cold Spring Harb Perspect Biol

203

191

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Section: The Centrosome and Its Duplication Cyclementioning

confidence: 99%

Section: The Centrosome and Its Duplication Cyclementioning

confidence: 99%

The Centrosome and Its Duplication Cycle

Hagan

Glover

2015

Cold Spring Harb Perspect Biol

203

191

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“…To investigate the effects of genomic instability and resulting aneuploidy on carcinogenesis, various mouse models have been developed, mainly by targeting mitotic or other cell cycle regulators (Foijer, Draviam, & Sorger, 2008; Rao, Yamada, Yao, & Dai, 2009; Ricke, van Ree, & van Deursen, 2008; Schvartzman, Sotillo, & Benezra, 2010). Shugoshin‐1 (Sgo1) protects cohesin proteins and centrosome integrity (Salic, Waters, & Mitchison, 2004; Schöckel, Möckel, Mayer, Boos, & Stemmann, 2011). Cohesins keep sister chromatids from prematurely separating during mitosis, thus ensuring mitotic fidelity (Hirano, 2015).…”

Section: Introductionmentioning

confidence: 99%

Spontaneous development of Alzheimer's disease‐associated brain pathology in a Shugoshin‐1 mouse cohesinopathy model

et al. 2018

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SummarySpontaneous late‐onset Alzheimer's disease (LOAD) accounts for more than 95% of all human AD. As mice do not normally develop AD and as understanding on molecular processes leading to spontaneous LOAD has been insufficient to successfully model LOAD in mouse, no mouse model for LOAD has been available. Existing mouse AD models are all early‐onset AD (EOAD) models that rely on forcible expression of AD‐associated protein(s), which may not recapitulate prerequisites for spontaneous LOAD. This limitation in AD modeling may contribute to the high failure rate of AD drugs in clinical trials. In this study, we hypothesized that genomic instability facilitates development of LOAD and tested two genomic instability mice models in the brain pathology at the old age. Shugoshin‐1 (Sgo1) haploinsufficient (∓) mice, a model of chromosome instability (CIN) with chromosomal and centrosomal cohesinopathy, spontaneously exhibited a major feature of AD pathology; amyloid beta accumulation that colocalized with phosphorylated Tau, beta‐secretase 1 (BACE), and mitotic marker phospho‐Histone H3 (p‐H3) in the brain. Another CIN model, spindle checkpoint‐defective BubR1−/+ haploinsufficient mice, did not exhibit the pathology at the same age, suggesting the prolonged mitosis‐origin of the AD pathology. RNA‐seq identified ten differentially expressed genes, among which seven genes have indicated association with AD pathology or neuronal functions (e.g., ARC, EBF3). Thus, the model represents a novel model that recapitulates spontaneous LOAD pathology in mouse. The Sgo1−/+ mouse may serve as a novel tool for investigating mechanisms of spontaneous progression of LOAD pathology, for early diagnosis markers, and for drug development.

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“…32 It turns out that separase also mediates timely centriole licensing. 31,[33][34][35] The cell utilizes separase's protease activity to cleave the tight intercentriolar linker to license duplication, thereby coupling centriole duplication mechanistically to the onset of sister-chromatid separation. 34,36 These data engendered the hypothesis that cohesin forms the tight intercentriolar linker.…”

Section: Excess Baggage: How Cancer Cells Acquire Extra Centrosomesmentioning

confidence: 99%

Let's huddle to prevent a muddle: centrosome declustering as an attractive anticancer strategy

2012

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Nearly a century ago, cell biologists postulated that the chromosomal aberrations blighting cancer cells might be caused by a mysterious organelle-the centrosome-that had only just been discovered. For years, however, this enigmatic structure was neglected in oncologic investigations and has only recently reemerged as a key suspect in tumorigenesis. A majority of cancer cells, unlike healthy cells, possess an amplified centrosome complement, which they manage to coalesce neatly at two spindle poles during mitosis. This clustering mechanism permits the cell to form a pseudo-bipolar mitotic spindle for segregation of sister chromatids. On rare occasions this mechanism fails, resulting in declustered centrosomes and the assembly of a multipolar spindle. Spindle multipolarity consigns the cell to an almost certain fate of mitotic arrest or death. The catastrophic nature of multipolarity has attracted efforts to develop drugs that can induce declustering in cancer cells. Such chemotherapeutics would theoretically spare healthy cells, whose normal centrosome complement should preclude multipolar spindle formation. In search of the 'Holy Grail' of nontoxic, cancer cell-selective, and superiorly efficacious chemotherapy, research is underway to elucidate the underpinnings of centrosome clustering mechanisms. Here, we detail the progress made towards that end, highlighting seminal work and suggesting directions for future research, aimed at demystifying this riddling cellular tactic and exploiting it for chemotherapeutic purposes. We also propose a model to highlight the integral role of microtubule dynamicity and the delicate balance of forces on which cancer cells rely for effective centrosome clustering. Finally, we provide insights regarding how perturbation of this balance may pave an inroad for inducing lethal centrosome dispersal and death selectively in cancer cells.

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Cleavage of cohesin rings coordinates the separation of centrioles and chromatids

Cited by 158 publications

References 40 publications

The Centrosome and Its Duplication Cycle

The Centrosome and Its Duplication Cycle

Spontaneous development of Alzheimer's disease‐associated brain pathology in a Shugoshin‐1 mouse cohesinopathy model

Let's huddle to prevent a muddle: centrosome declustering as an attractive anticancer strategy

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