scholarly journals The Human Kinesin Kif18A’s Neck Linker Permits Navigation of Microtubule Bound Obstacles within the Mitotic Spindle

2018 ◽  
Author(s):  
Heidi L. H. Malaby ◽  
Dominique V. Lessard ◽  
Christopher L. Berger ◽  
Jason Stumpff
Keyword(s):  
Single Molecule ◽  
Mitotic Spindle ◽  
Mammalian Cells ◽  
Mitotic Chromosome ◽  
Genetic Material ◽  
Daughter Cells ◽  
Chromosome Alignment ◽  
A Cell ◽  
Fiber Dynamics ◽  
Robust Separation

AbstractMitotic chromosome alignment is essential for the robust separation of genetic material into daughter cells. In mammalian cells, this process requires the function of Kif18A, a kinesin-8 motor protein. Kif18A confines chromosome movement to the mitotic spindle equator by accumulating at the plus-ends of kinetochore microtubule bundles (K-fibers), where it functions to suppress K-fiber dynamics. It is not understood how the motor accumulates at K-fiber plus-ends, a difficult feat requiring the motor to navigate protein dense microtubule tracks. Our data indicate that Kif18A’s relatively long (17 amino acid) neck linker is required for the motor’s accumulation at K-fiber plus-ends. Shorter neck linker (sNL) variants of Kif18A display a deficiency in K-fiber accumulation, especially on K-fibers near the center of the spindle. This pattern correlates with the more uniform concentration of the microtubule bundling protein HURP on central K-fibers compared to peripheral K-fibers. Depletion of HURP permits Kif18A sNL to accumulate on central K-fibers, while HURP overexpression reduces wild-type Kif18A’s ability to accumulate on this same K-fiber subset. Furthermore, single molecule assays indicate that Kif18A sNL motors are less proficient at navigating microtubules coated with the microtubule associated protein tau. Taken together, these results support a model in which Kif18A’s neck linker length permits efficient navigation of obstacles such as HURP to reach K-fiber ends during mitosis.Signficiance StatementKinesin motor proteins play key roles in controlling chromosome alignment and segregation during cell division. The kinesin Kif18A confines chromosomes to the middle of the spindle by accumulating at the ends of microtubules attached to chromosomes. We show here that Kif18A’s ability to accumulate at the end of these microtubules requires navigation of microtubule-associated protein obstacles, and that this activity is imparted by a relatively long neck linker region. These findings demonstrate a molecular mechanism for navigation of densely populated microtubules inside a cell.

scholarly journals KIF18A's neck linker permits navigation of microtubule-bound obstacles within the mitotic spindle

2019 ◽  
Vol 2 (1) ◽  
pp. e201800169 ◽  
Author(s):  
Heidi LH Malaby ◽  
Dominique V Lessard ◽  
Christopher L Berger ◽  
Jason Stumpff
Keyword(s):  
Single Molecule ◽  
Mitotic Spindle ◽  
Binding Proteins ◽  
Mitotic Chromosome ◽  
Chromosome Movement ◽  
Wild Type ◽  
Microtubule Associated Proteins ◽  
Chromosome Alignment ◽  
Associated Proteins ◽  
Fiber Dynamics

KIF18A (kinesin-8) is required for mammalian mitotic chromosome alignment. KIF18A confines chromosome movement to the mitotic spindle equator by accumulating at the plus-ends of kinetochore microtubule bundles (K-fibers), where it functions to suppress K-fiber dynamics. It is not understood how the motor accumulates at K-fiber plus-ends, a difficult feat requiring the motor to navigate protein dense microtubule tracks. Our data indicate that KIF18A's relatively long neck linker is required for the motor's accumulation at K-fiber plus-ends. Shorter neck linker (sNL) variants of KIF18A display a deficiency in accumulation at the ends of K-fibers at the center of the spindle. Depletion of K-fiber–binding proteins reduces the KIF18A sNL localization defect, whereas their overexpression reduces wild-type KIF18A's ability to accumulate on this same K-fiber subset. Furthermore, single-molecule assays indicate that KIF18A sNL motors are less proficient in navigating microtubules coated with microtubule-associated proteins. Taken together, these results support a model in which KIF18A's neck linker length permits efficient navigation of obstacles to reach K-fiber ends during mitosis.

scholarly journals Regulation of the cell cycle and centrosome biology by deubiquitylases

2017 ◽  
Vol 45 (5) ◽  
pp. 1125-1136 ◽  
Author(s):  
Sarah Darling ◽  
Andrew B. Fielding ◽  
Dorota Sabat-Pośpiech ◽  
Ian A. Prior ◽  
Judy M. Coulson
Keyword(s):  
Cell Cycle ◽  
Cell Division ◽  
Mitotic Spindle ◽  
Mammalian Cells ◽  
Genetic Material ◽  
Post Translational Modification ◽  
Cellular Processes ◽  
Daughter Cells ◽  
Damage Response ◽  
A Cell

Post-translational modification of proteins by ubiquitylation is increasingly recognised as a highly complex code that contributes to the regulation of diverse cellular processes. In humans, a family of almost 100 deubiquitylase enzymes (DUBs) are assigned to six subfamilies and many of these DUBs can remove ubiquitin from proteins to reverse signals. Roles for individual DUBs have been delineated within specific cellular processes, including many that are dysregulated in diseases, particularly cancer. As potentially druggable enzymes, disease-associated DUBs are of increasing interest as pharmaceutical targets. The biology, structure and regulation of DUBs have been extensively reviewed elsewhere, so here we focus specifically on roles of DUBs in regulating cell cycle processes in mammalian cells. Over a quarter of all DUBs, representing four different families, have been shown to play roles either in the unidirectional progression of the cell cycle through specific checkpoints, or in the DNA damage response and repair pathways. We catalogue these roles and discuss specific examples. Centrosomes are the major microtubule nucleating centres within a cell and play a key role in forming the bipolar mitotic spindle required to accurately divide genetic material between daughter cells during cell division. To enable this mitotic role, centrosomes undergo a complex replication cycle that is intimately linked to the cell division cycle. Here, we also catalogue and discuss DUBs that have been linked to centrosome replication or function, including centrosome clustering, a mitotic survival strategy unique to cancer cells with supernumerary centrosomes.

scholarly journals Kinetochore-microtubule stability governs the metaphase requirement for Eg5

2014 ◽  
Vol 25 (13) ◽  
pp. 2051-2060 ◽  
Author(s):  
A. Sophia Gayek ◽  
Ryoma Ohi
Keyword(s):  
Physical Properties ◽  
Human Cell ◽  
Mitotic Spindle ◽  
Mammalian Cells ◽  
Human Cell Lines ◽  
Bipolar Spindle ◽  
Daughter Cells ◽  
Microtubule Stability ◽  
The Stability ◽  
Bipolar Spindles

The mitotic spindle is a bipolar, microtubule (MT)-based cellular machine that segregates the duplicated genome into two daughter cells. The kinesin-5 Eg5 establishes the bipolar geometry of the mitotic spindle, but previous work in mammalian cells suggested that this motor is unimportant for the maintenance of spindle bipolarity. Although it is known that Kif15, a second mitotic kinesin, enforces spindle bipolarity in the absence of Eg5, how Kif15 functions in this capacity and/or whether other biochemical or physical properties of the spindle promote its bipolarity have been poorly studied. Here we report that not all human cell lines can efficiently maintain bipolarity without Eg5, despite their expressing Kif15. We show that the stability of chromosome-attached kinetochore-MTs (K-MTs) is important for bipolar spindle maintenance without Eg5. Cells that efficiently maintain bipolar spindles without Eg5 have more stable K-MTs than those that collapse without Eg5. Consistent with this observation, artificial destabilization of K-MTs promotes spindle collapse without Eg5, whereas stabilizing K-MTs improves bipolar spindle maintenance without Eg5. Our findings suggest that either rapid K-MT turnover pulls poles inward or slow K-MT turnover allows for greater resistance to inward-directed forces.

scholarly journals Contribution of hCAP-D2, a Non-SMC Subunit of Condensin I, to Chromosome and Chromosomal Protein Dynamics during Mitosis

2005 ◽  
Vol 25 (2) ◽  
pp. 740-750 ◽  
Author(s):  
Erwan Watrin ◽  
Vincent Legagneux
Keyword(s):  
Rna Interference ◽  
Mitotic Spindle ◽  
Topoisomerase Ii ◽  
Mitotic Chromosome ◽  
Chromosomal Protein ◽  
Structural Components ◽  
Mitotic Chromosomes ◽  
Sister Chromatids ◽  
Chromosome Alignment ◽  
Structural Maintenance Of Chromosomes

ABSTRACT Condensins are heteropentameric complexes that were first identified as structural components of mitotic chromosomes. They are composed of two SMC (structural maintenance of chromosomes) and three non-SMC subunits. Condensins play a role in the resolution and segregation of sister chromatids during mitosis, as well as in some aspects of mitotic chromosome assembly. Two distinct condensin complexes, condensin I and condensin II, which differ only in their non-SMC subunits, exist. Here, we used an RNA interference approach to deplete hCAP-D2, a non-SMC subunit of condensin I, in HeLa cells. We found that the association of hCAP-H, another non-SMC subunit of condensin I, with mitotic chromosomes depends on the presence of hCAP-D2. Moreover, chromatid axes, as defined by topoisomerase II and hCAP-E localization, are disorganized in the absence of hCAP-D2, and the resolution and segregation of sister chromatids are impaired. In addition, hCAP-D2 depletion affects chromosome alignment in metaphase and delays entry into anaphase. This suggests that condensin I is involved in the correct attachment between chromosome kinetochores and microtubules of the mitotic spindle. These results are discussed relative to the effects of depleting both condensin complexes.

scholarly journals Investigating the Central Dogma of Molecular Biology in the Context of Nuclear Architecture and Cell Cycle

2019 ◽  
Author(s):  
Shivnarayan Dhuppar ◽  
Aprotim Mazumder
Keyword(s):  
Gene Expression ◽  
Cell Cycle ◽  
Single Molecule ◽  
Mammalian Cells ◽  
Nuclear Architecture ◽  
Nuclear Lamina ◽  
Gene Copy ◽  
A Cell ◽  
Cycle Dependent

AbstractNuclear architecture is the organization of the genome within a cell nucleus with respect to different nuclear landmarks such as nuclear lamina, matrix or nucleoli. Lately it has emerged as a major regulator of gene expression in mammalian cells. The studies connecting nuclear architecture with gene expression are largely population-averaged and do not report on the heterogeneity in genome organization or in gene expression within a population. In this report we present a method for combining 3D DNA Fluorescence in situ Hybridization (FISH) with single molecule RNA FISH (smFISH) and immunofluorescence to study nuclear architecture-dependent gene regulation on a cell-by-cell basis. We further combine it with an imaging-based cell cycle staging to correlate nuclear architecture with gene expression across the cell cycle. We present this in the context of Cyclin A2 (CCNA2) gene for its known cell cycle-dependent expression. We show that, across the cell cycle, the expression of a CCNA2 gene copy is stochastic and depends neither on its sub-nuclear position—which usually lies close to nuclear lamina—nor on the expression from the other copies.

scholarly journals Cytokinesis in Eukaryotic Cells: The Furrow Complexity at a Glance

Cells ◽  
2020 ◽  
Vol 9 (2) ◽  
pp. 271 ◽  
Author(s):  
Roberta Fraschini
Keyword(s):  
Cell Division ◽  
Asymmetric Cell Division ◽  
Animal Cell ◽  
Genetic Material ◽  
Model Organism ◽  
Complex Phase ◽  
Daughter Cells ◽  
Viable Cells ◽  
A Cell ◽  
Duplication Cycle

The duplication cycle is the fascinating process that, starting from a cell, results in the formation of two daughter cells and it is essential for life. Cytokinesis is the final step of the cell cycle, it is a very complex phase, and is a concert of forces, remodeling, trafficking, and cell signaling. All of the steps of cell division must be properly coordinated with each other to faithfully segregate the genetic material and this task is fundamental for generating viable cells. Given the importance of this process, molecular pathways and proteins that are involved in cytokinesis are conserved from yeast to humans. In this review, we describe symmetric and asymmetric cell division in animal cell and in a model organism, budding yeast. In addition, we illustrate the surveillance mechanisms that ensure a proper cell division and discuss the connections with normal cell proliferation and organs development and with the occurrence of human diseases.

Tubulin post-translational modifications and the construction of microtubular organelles in Trypanosoma brucei

1988 ◽  
Vol 90 (4) ◽  
pp. 577-589 ◽  
Author(s):  
R. Sasse ◽  
K. Gull
Keyword(s):  
Cell Cycle ◽  
Trypanosoma Brucei ◽  
Mitotic Spindle ◽  
Post Translational Modification ◽  
Post Translational Modifications ◽  
Alpha Tubulin ◽  
Daughter Cells ◽  
A Cell ◽  
Microtubular Organelles ◽  
Tubulin Content

We have used specific monoclonal antibodies to facilitate a study of acetylated and tyrosinated alpha-tubulin in the microtubule (MT) arrays in the Trypanosoma brucei cell. Acetylated alpha-tubulin is not solely located in the stable microtubular arrays but is present even in the ephemeral microtubules of the mitotic spindle. Moreover, there is a uniform distribution of this isoform in all arrays. Studies of flagella complexes show that acetylation is concomitant with assembly of MTs. There is no subsequent major modulation in the content of acetylated alpha-tubulin in MTs. Conversely, polymerizing flagellar MTs have a high tyrosinated alpha-tubulin content, which is subsequently reduced to a basal level at a discrete point in the cell cycle. The MTs of the intranuclear mitotic spindle appear never to contain tyrosinated alpha-tubulin, suggesting that they are actually constructed of detyrosinated alpha-tubulin or that detyrosination is extremely rapid at this time in the cell cycle. T. brucei therefore, represents a cell type with extremely active mechanisms for the post-translational modification of alpha-tubulin. Our analyses of the timing of acquisition and modulation in relation to MT construction in T. brucei, suggest that acetylation and detyrosination of alpha-tubulin are two independently regulated post-translational modifications, that are not uniquely associated with particular subsets of MTs of defined lability, position or function. Post-assembly detyrosination of alpha-tubulin may provide a mechanism whereby the cell could discriminate between new and old MTs, during construction of the cytoskeleton through the cell cycle. However, we also suggest that continuation of detyrosination, allows the cell, at cell division, to partition into daughter cells two equivalent sets of cytoskeletal MTs.

The Role of the Centrosome in Development and Progression of Breast Cancer

2001 ◽  
Vol 7 (S2) ◽  
pp. 582-583
Author(s):  
W. Lingle ◽  
J. Salisbury ◽  
S. Barrett ◽  
V. Negron ◽  
C. Whitehead
Keyword(s):  
Mitotic Spindle ◽  
Mammalian Cells ◽  
Microtubule Organizing Center ◽  
Daughter Cells ◽  
Spindle Poles ◽  
Sister Chromatids ◽  
Close Proximity ◽  
Interphase Cells ◽  
Organizing Center

The centrosome is the major microtubule organizing center in most mammalian cells, and as such it determines the number, polarity, and spatial distribution of microtubules (MTs). Interphase MTs, together with actin and intermediate filaments, constitute the cell's cytoskeleton, which dynamically maintains cell polarity and tissue architecture. Interphase cells begin Gl of the cell cycle with one centrosome. During S phase, the centrosome duplicates concomitantly with DNA replication. Duplicated centrosomes usually remain in close proximity to one another until late G2, at which time they separate and then move during prophase to become the poles that organize the bipolar mitotic spindle. During the G2/M transition, interphase MTs depolymerize and a new population of highly dynamic mitotic MTs are nucleated at the spindle poles. The bipolar mitotic spindle apparatus constitutes the machinery that partitions and separates sister chromatids equally between two daughter cells.

scholarly journals Cytoplasmic dynein crosslinks and slides anti-parallel microtubules using its two motor domains

eLife ◽  
2013 ◽  
Vol 2 ◽  
Author(s):  
Marvin E Tanenbaum ◽  
Ronald D Vale ◽  
Richard J McKenney
Keyword(s):  
Single Molecule ◽  
Mitotic Spindle ◽  
Mammalian Cells ◽  
Motor Proteins ◽  
Cytoplasmic Dynein ◽  
Eukaryotic Cells ◽  
Reverse Direction ◽  
Tail Domain ◽  
Mitotic Spindles

Cytoplasmic dynein is the predominant minus-end-directed microtubule (MT) motor in most eukaryotic cells. In addition to transporting vesicular cargos, dynein helps to organize MTs within MT networks such as mitotic spindles. How dynein performs such non-canonical functions is unknown. Here we demonstrate that dynein crosslinks and slides anti-parallel MTs in vitro. Surprisingly, a minimal dimeric motor lacking a tail domain and associated subunits can cause MT sliding. Single molecule imaging reveals that motors pause and frequently reverse direction when encountering an anti-parallel MT overlap, suggesting that the two motor domains can bind both MTs simultaneously. In the mitotic spindle, inward microtubule sliding by dynein counteracts outward sliding generated by kinesin-5, and we show that a tailless, dimeric motor is sufficient to drive this activity in mammalian cells. Our results identify an unexpected mechanism for dynein-driven microtubule sliding, which differs from filament sliding mechanisms described for other motor proteins.

scholarly journals The Unresolved Problem of DNA Bridging

Genes ◽  
2018 ◽  
Vol 9 (12) ◽  
pp. 623 ◽  
Author(s):  
María Fernández-Casañas ◽  
Kok-Lung Chan
Keyword(s):  
Chromosome Segregation ◽  
Genome Stability ◽  
Genetic Material ◽  
Genome Integrity ◽  
Cellular Division ◽  
Daughter Cells ◽  
Dna Replication And Repair ◽  
A Cell ◽  
Chromosome Separation ◽  
Last Stage

Accurate duplication and transmission of identical genetic information into offspring cells lies at the heart of a cell division cycle. During the last stage of cellular division, namely mitosis, the fully replicated DNA molecules are condensed into X-shaped chromosomes, followed by a chromosome separation process called sister chromatid disjunction. This process allows for the equal partition of genetic material into two newly born daughter cells. However, emerging evidence has shown that faithful chromosome segregation is challenged by the presence of persistent DNA intertwining structures generated during DNA replication and repair, which manifest as so-called ultra-fine DNA bridges (UFBs) during anaphase. Undoubtedly, failure to disentangle DNA linkages poses a severe threat to mitosis and genome integrity. This review will summarize the possible causes of DNA bridges, particularly sister DNA inter-linkage structures, in an attempt to explain how they may be processed and how they influence faithful chromosome segregation and the maintenance of genome stability.

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