Structure of the MIS12 Complex and Molecular Basis of Its Interaction with CENP-C at Human Kinetochores

Petrovic, Arsen; Keller, Jenny; Liu, Yahui; Overlack, Katharina; John, Juliane; Dimitrova, Yoana N.; Jenni, Simon; Gerwen, Suzan van; Stege, Patricia; Wohlgemuth, Sabine; Rombaut, Pascaline; Herzog, Franz; Harrison, Stephen C.; Vetter, Ingrid R.; Musacchio, Andrea

doi:10.1016/j.cell.2016.10.005

Cited by 154 publications

(279 citation statements)

References 84 publications

(166 reference statements)

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“…Both these interactions are sensitive to phosphorylation of residues in a Dsn1 aminoterminal extension that projects from head 2 (Akiyoshi et al 2013). When not phosphorylated, this segment of Dsn1 binds head 1 and blocks the sites for Mif2 and Ame1 Petrovic et al 2016). Phosphorylation at two positions (serines 240 and 250 in Saccharomyces cerevisiae) by Ipl1…”

Section: Pmf1mentioning

confidence: 99%

“…Thus, Cnn1:Wip1, presumably with associated Ndc80 complexes, may enhance kinetochore strength or connectivity but probably does not modify its fundamental molecular organization. The two adaptors bind Spc24:Spc25 through related motifs-at the carboxy-terminal end of the MIND subunit Dsn1 and near the aminoterminal end of Cnn1 (Bock et al 2012;Malvezzi et al 2013;Dimitrova et al 2016;Petrovic et al 2016). Mps1 phosphorylation of a serine residue in the binding segment of Cnn1 blocks the interaction (Thapa et al 2015); serine residues in the related Dsn1 segment are potential sites of phosphoregulation, but a role for their modification, if any, has yet to be identified .…”

Section: Two Adaptor Complexes-mindmentioning

confidence: 99%

“…MIND is a 210-Å-long, heterotetrameric rod, with two globular, four-helix bundles ("heads") at one end Petrovic et al 2016). Mtw1 MIS12 and Nnf1…”

Section: Two Adaptor Complexes-mindmentioning

confidence: 99%

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Molecular Structures of Yeast Kinetochore Subcomplexes and Their Roles in Chromosome Segregation

Jenni

Dimitrova

Valverde

et al. 2017

Cold Spring Harb Symp Quant Biol

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Kinetochore molecular architecture exemplifies "form follows function." The simplifications that generated the one-chromosome:one-microtubule linkage in point-centromere yeast have enabled strategies for systematic structural analysis and highresolution visualization of many kinetochore components, leading to specific proposals for molecular mechanisms. We describe here some structural features that allow a kinetochore to remain attached to the end of a depolymerizing microtubule (MT) and some characteristics of the connections between substructures that permit very sensitive regulation by differential kinase activities. We emphasize in particular the importance of flexible connections between rod-like structural members and the integration of these members into a compliant cage-like assembly anchored on the MT by a sliding molecular ring.

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Section: Pmf1mentioning

confidence: 99%

Section: Two Adaptor Complexes-mindmentioning

confidence: 99%

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Molecular Structures of Yeast Kinetochore Subcomplexes and Their Roles in Chromosome Segregation

Jenni

Dimitrova

Valverde

et al. 2017

Cold Spring Harb Symp Quant Biol

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“…B (left to right = microtubule plus-end to centromere) The conserved, dual pathways (solid arrows – direct interaction, dashed arrow – indirect interaction) that assemble the KMN network, which forms the interface of the kinetochore with the microtubule plus-end. C Reconstruction of the protein architecture of the budding yeast kinetochore using fluorescence microscopy measurements and protein structures [7, 8, 14, 15, 32, 33, 48–50, 73]. Centromere-associated proteins are represented by white, oblong shapes.…”

Section: Figurementioning

confidence: 99%

How Kinetochore Architecture Shapes the Mechanisms of Its Function

Joglekar

Kukreja

2017

Current Biology

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The eukaryotic kinetochore is a sophisticated multi-protein machine that segregates chromosomes during cell division. To ensure accurate chromosome segregation, it performs three major functions using disparate molecular mechanisms. It operates a mechanosensitive signaling cascade known as the Spindle Assembly Checkpoint (SAC) to detect and signal the lack of attachment to spindle microtubules, and delay anaphase onset in response. After attaching to spindle microtubules, the kinetochore generates the force necessary to move chromosomes. Finally, if the two sister kinetochores on a chromosome are both attached to microtubules emanating from the same spindle pole, they activate another mechanosensitive mechanism to correct the monopolar attachments. All three functions maintain genome stability during cell division. The outlines of the biochemical activities responsible for these functions are now available. How the kinetochore integrates the underlying molecular mechanisms is still being elucidated. In this review, we will discuss how the nanoscale protein organization in the kinetochore, which we refer to as kinetochore ‘architecture’, organizes its biochemical activities to facilitate the realization and integration of emergent mechanisms underlying its three major functions. For this discussion, we will use the relatively simple budding yeast kinetochore as a model, and extrapolate insights gained from this model to elucidate functional roles of the architecture of the much more complex human kinetochore.

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“…Coupling performance improved with the incorporation of additional microtubule-binding kinetochore elements [153,154], with the use of native kinetochore particles isolated from yeast [43], and with the use of flexible tethers for linking sub-complexes to beads [155]. Further improvements seem likely, especially as continued advancements in kinetochore biochemistry enable reconstitutions of ever more complete and stable kinetochore assemblies [156][157][158]. However, the performance achieved in laser trap tip-coupling assays already provides a reasonably good match to physiological conditions.…”

Section: Purified Kinetochores and Sub-complexes Are Excellent Tip-comentioning

confidence: 99%

Anaphase A: Melting Microtubules Move Chromosomes toward Spindle Poles

Cl¹

2017

Preprint

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Abstract:The separation of sister chromatids during anaphase is the culmination of mitosis and one of the most strikingly beautiful examples of cellular movement. It consists of two distinct processes: Anaphase A, the movement of chromosomes toward spindle poles via shortening of the connecting fibers, and anaphase B, separation of the two poles from one another via spindle elongation. I focus here on anaphase A chromosome-to-pole movement. The chapter begins by summarizing classical observations of chromosome movements, which support the current understanding of anaphase mechanisms. Live cell fluorescence microscopy studies showed that poleward chromosome movement is associated with disassembly, or 'melting' of the kinetochore-attached microtubule fibers that link chromosomes to poles. Microtubule-marking techniques established that kinetochore-fiber disassembly often occurs through a 'pac-man' mechanism, where tubulin subunits are lost from kinetochore-attached plus ends and the kinetochore appears to consume its microtubule track as it moves poleward. In addition, kinetochore-fiber disassembly in many cells occurs partly through 'flux', where the microtubules flow continuously toward the poles and tubulin subunits are lost from minus ends. Molecular mechanistic models for how load-bearing attachments are maintained to disassembling microtubule ends, and how the forces are generated to drive pac-man and flux-based movements, are discussed.

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Structure of the MIS12 Complex and Molecular Basis of Its Interaction with CENP-C at Human Kinetochores

Cited by 154 publications

References 84 publications

Molecular Structures of Yeast Kinetochore Subcomplexes and Their Roles in Chromosome Segregation

Molecular Structures of Yeast Kinetochore Subcomplexes and Their Roles in Chromosome Segregation

How Kinetochore Architecture Shapes the Mechanisms of Its Function

Anaphase A: Melting Microtubules Move Chromosomes toward Spindle Poles

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