Your search keyword '"Larisa Gheber"' showing total 22 results

1. The kinesin-5 tail domain directly modulates the mechanochemical cycle of the motor domain for anti-parallel microtubule sliding

Author

Tatyana Bodrug, Elizabeth M Wilson-Kubalek, Stanley Nithianantham, Alex F Thompson, April Alfieri, Ignas Gaska, Jennifer Major, Garrett Debs, Sayaka Inagaki, Pedro Gutierrez, Larisa Gheber, Richard J McKenney, Charles Vaughn Sindelar, Ronald Milligan, Jason Stumpff, Steven S Rosenfeld, Scott T Forth, and Jawdat Al-Bassam

Subjects

kinesin-5, motor protein, Microtubule, sliding, mitosis, mitotic spindle, Medicine, Science, Biology (General), QH301-705.5

Abstract

Kinesin-5 motors organize mitotic spindles by sliding apart microtubules. They are homotetramers with dimeric motor and tail domains at both ends of a bipolar minifilament. Here, we describe a regulatory mechanism involving direct binding between tail and motor domains and its fundamental role in microtubule sliding. Kinesin-5 tails decrease microtubule-stimulated ATP-hydrolysis by specifically engaging motor domains in the nucleotide-free or ADP states. Cryo-EM reveals that tail binding stabilizes an open motor domain ATP-active site. Full-length motors undergo slow motility and cluster together along microtubules, while tail-deleted motors exhibit rapid motility without clustering. The tail is critical for motors to zipper together two microtubules by generating substantial sliding forces. The tail is essential for mitotic spindle localization, which becomes severely reduced in tail-deleted motors. Our studies suggest a revised microtubule-sliding model, in which kinesin-5 tails stabilize motor domains in the microtubule-bound state by slowing ATP-binding, resulting in high-force production at both homotetramer ends.

Published

2020

2. Synthetic-Evolution Reveals Narrow Paths to Regulation of the Saccharomyces cerevisiae Mitotic Kinesin-5 Cin8

Author

Alina Goldstein, Mart Loog, Larisa Gheber, Liam J. Holt, Darya Goldman, and Ervin Valk

Subjects

Models, Molecular, Cdk1, Saccharomyces cerevisiae Proteins, Saccharomyces cerevisiae, Kinesins, Spindle Apparatus, environment and public health, Applied Microbiology and Biotechnology, Evolution, Molecular, phosphoregulation, 03 medical and health sciences, kinesin-5, Sequence Analysis, Protein, Single site, anaphase B, CDC2 Protein Kinase, Amino Acid Sequence, Phosphorylation, Molecular Biology, Mitosis, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0303 health sciences, Cyclin-dependent kinase 1, Binding Sites, biology, Chemistry, Cell Biology, Cin8, biology.organism_classification, Phenotype, Cell biology, enzymes and coenzymes (carbohydrates), Amino Acid Substitution, Kinesin, Function (biology), Research Paper, Developmental Biology

Abstract

Cdk1 has been found to phosphorylate the majority of its substrates in disordered regions, but some substrates maintain precise phosphosite positions over billions of years. Here, we examined the phosphoregulation of the kinesin-5, Cin8, using synthetic Cdk1-sites. We first analyzed the three native Cdk1 sites within the catalytic motor domain. Any single site conferred regulation, but to different extents. Synthetic sites were then systematically generated by single amino-acid substitutions, starting from a phosphodeficient variant of Cin8. Out of 29 synthetic Cdk1 sites, 8 disrupted function; 19 were neutral, similar to the phospho-deficient variant; and only two gave rise to phosphorylation-dependent spindle phenotypes. Of these two, one was immediately adjacent to a native Cdk1 site. Only one novel site position resulted in phospho-regulation. This site was sampled elsewhere in evolution, but the synthetic version was inefficient in S. cerevisiae. This study shows that a single phosphorylation site can modulate complex spindle dynamics, but likely requires further evolution to optimally regulate the precise reaction cycle of a mitotic motor.

Published

2019

3. Mechanisms by Which Kinesin-5 Motors Perform Their Multiple Intracellular Functions

Author

Alina Goldstein-Levitin, Larisa Gheber, Himanshu Pandey, and Mary Popov

Subjects

Computer science, QH301-705.5, Intracellular Space, Kinesins, Motility, Spindle Apparatus, macromolecular substances, Review, Models, Biological, Catalysis, Inorganic Chemistry, Motor protein, microtubules, Microtubule, kinesin-5, Animals, Humans, Physical and Theoretical Chemistry, Biology (General), Molecular Biology, Mitosis, QD1-999, Spectroscopy, mitosis, Organic Chemistry, General Medicine, Computer Science Applications, Chemistry, Kinesin, cell-cycle regulation of kinesin activity, Protein Processing, Post-Translational, Neuroscience, Intracellular

Abstract

Bipolar kinesin-5 motor proteins perform multiple intracellular functions, mainly during mitotic cell division. Their specialized structural characteristics enable these motors to perform their essential functions by crosslinking and sliding apart antiparallel microtubules (MTs). In this review, we discuss the specialized structural features of kinesin-5 motors, and the mechanisms by which these features relate to kinesin-5 functions and motile properties. In addition, we discuss the multiple roles of the kinesin-5 motors in dividing as well as in non-dividing cells, and examine their roles in pathogenetic conditions. We describe the recently discovered bidirectional motility in fungi kinesin-5 motors, and discuss its possible physiological relevance. Finally, we also focus on the multiple mechanisms of regulation of these unique motor proteins.

Published

2021

4. Bidirectional motility of kinesin-5 motor proteins: structural determinants, cumulative functions and physiological roles

Author

Jawdat Al-Bassam, Himanshu Pandey, Sudhir Kumar Singh, and Larisa Gheber

Subjects

0301 basic medicine, Saccharomyces cerevisiae Proteins, Movement, Kinesins, Motility, Saccharomyces cerevisiae, macromolecular substances, Biology, Spindle pole body, Motor protein, 03 medical and health sciences, Cellular and Molecular Neuroscience, Microtubule, Animals, Humans, Directionality, Molecular Biology, Mitosis, Pharmacology, Molecular Motor Proteins, Cell Biology, Spindle apparatus, Cell biology, 030104 developmental biology, Molecular Medicine, Kinesin, Protein Multimerization

Abstract

Mitotic kinesin-5 bipolar motor proteins perform essential functions in mitotic spindle dynamics by crosslinking and sliding antiparallel microtubules (MTs) apart within the mitotic spindle. Two recent studies have indicated that single molecules of Cin8, the Saccharomyces cerevisiae kinesin-5 homolog, are minus end-directed when moving on single MTs, yet switch directionality under certain experimental conditions (Gerson-Gurwitz et al., EMBO J 30:4942-4954, 2011; Roostalu et al., Science 332:94-99, 2011). This finding was unexpected since the Cin8 catalytic motor domain is located at the N-terminus of the protein, and such kinesins have been previously thought to be exclusively plus end-directed. In addition, the essential intracellular functions of kinesin-5 motors in separating spindle poles during mitosis can only be accomplished by plus end-directed motility during antiparallel sliding of the spindle MTs. Thus, the mechanism and possible physiological role of the minus end-directed motility of kinesin-5 motors remain unclear. Experimental and theoretical studies from several laboratories in recent years have identified additional kinesin-5 motors that are bidirectional, revealed structural determinants that regulate directionality, examined the possible mechanisms involved and have proposed physiological roles for the minus end-directed motility of kinesin-5 motors. Here, we summarize our current understanding of the remarkable ability of certain kinesin-5 motors to switch directionality when moving along MTs.

Published

2018

5. The kinesin-5 tail domain directly modulates the mechanochemical cycle of the motor domain for anti-parallel microtubule sliding

Author

Pedro Gutierrez, April Alfieri, Jason Stumpff, Alex F. Thompson, Larisa Gheber, Garrett Debs, Jawdat Al-Bassam, Scott Forth, Ignas Gaska, Tatyana Bodrug, Sayaka Inagaki, Steven S. Rosenfeld, Elizabeth M. Wilson-Kubalek, Charles V. Sindelar, Jennifer Major, Richard J. McKenney, Ronald A. Milligan, and Stanley Nithianantham

Subjects

Structural Biology and Molecular Biophysics, sliding, Kinesins, Microtubules, Adenosine Triphosphate, cell biology, structural biology, Biology (General), Physics, 0303 health sciences, D. melanogaster, General Neuroscience, Hydrolysis, 030302 biochemistry & molecular biology, General Medicine, Microtubule sliding, Adenosine Diphosphate, mitotic spindle, Medicine, Kinesin, Protein Binding, Research Article, Human, Zipper, QH301-705.5, Science, 1.1 Normal biological development and functioning, Microtubule, Spindle Apparatus, General Biochemistry, Genetics and Molecular Biology, Motor protein, 03 medical and health sciences, Protein Domains, Underpinning research, kinesin-5, motor protein, molecular biophysics, Humans, human, Mitosis, 030304 developmental biology, mitosis, General Immunology and Microbiology, Cryoelectron Microscopy, Cell Biology, Spindle apparatus, Kinetics, Structural biology, Biophysics, Generic health relevance, Biochemistry and Cell Biology

Abstract

Kinesin-5 motors organize mitotic spindles by sliding apart microtubules. They are homotetramers with dimeric motor and tail domains at both ends of a bipolar minifilament. Here, we describe a regulatory mechanism involving direct binding between tail and motor domains and its fundamental role in microtubule sliding. Kinesin-5 tails decrease microtubule-stimulated ATP-hydrolysis by specifically engaging motor domains in the nucleotide-free or ADP states. Cryo-EM reveals that tail binding stabilizes an open motor domain ATP-active site. Full-length motors undergo slow motility and cluster together along microtubules, while tail-deleted motors exhibit rapid motility without clustering. The tail is critical for motors to zipper together two microtubules by generating substantial sliding forces. The tail is essential for mitotic spindle localization, which becomes severely reduced in tail-deleted motors. Our studies suggest a revised microtubule-sliding model, in which kinesin-5 tails stabilize motor domains in the microtubule-bound state by slowing ATP-binding, resulting in high-force production at both homotetramer ends.

Published

2019

6. The Kinesin-5 Tail Domain Directly Modulates the Mechanochemical Cycle of the Motor for Anti-Parallel Microtubule Sliding

Author

Pedro Gutierrez, Larisa Gheber, Jawdat Al-Bassam, Stanley Nithianantham, Scott Forth, Alex F. Thompson, Elizabeth M. Wilson-Kubalek, Jason Stumpff, Ronald A. Milligan, Tatyana Bodrug, Steven S. Rosenfeld, Ignas Gaska, Sayaka Inagaki, Charles V. Sindelar, Jennifer Major, Richard J. McKenney, April Alfieri, and Garrett Debs

Subjects

0303 health sciences, Zipper, Chemistry, Motility, Microtubule sliding, Antiparallel (biochemistry), Spindle apparatus, 03 medical and health sciences, 0302 clinical medicine, Microtubule, Biophysics, Kinesin, Mitosis, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Kinesin-5 motors organize mitotic spindles by sliding apart anti-parallel microtubules. They are homotetramers composed of two antiparallel dimers placing orthogonal motor and tail domains at opposite ends of a bipolar minifilament. Here, we describe a regulatory mechanism, involving direct binding of the tail to motor domain and reveal its fundamental role in microtubule sliding motility. Biochemical analyses reveal that the tail down-regulates microtubule-activated ATP hydrolysis by specifically engaging the motor in the nucleotide-free or ADP-bound states. Cryo-EM structures reveal that the tail stabilizes a unique conformation of the motor N-terminal subdomain opening its active site. Full-length kinesin-5 motors undergo slow motility and cluster together along microtubules, while tail-deleted motors exhibit rapid motility without clustering along microtubules. The tail is critical for motors to zipper together two microtubules by generating substantial forces within sliding zones. The tail domain is essential for kinesin-5 mitotic spindle localization in vivo, which becomes severely reduced when the tail is deleted. Our studies suggest a revised microtubule-sliding model, in which tail domains directly engage motor domains at both ends of kinesin-5 homotetramers enhancing stability of the dual microtubule-bound states leading to slow motility yet high force production.

Published

2019

7. Synthetic-evolution reveals that phosphoregulation of the mitotic kinesin-5 Cin8 is constrained

Author

Alina Goldstein, Mart Loog, Liam J. Holt, Larisa Gheber, Ervin Valk, and Darya Goldman

Subjects

0303 health sciences, Cyclin-dependent kinase 1, Phosphorylation sites, Chemistry, environment and public health, Phenotype, Cell biology, Motor protein, enzymes and coenzymes (carbohydrates), 03 medical and health sciences, 0302 clinical medicine, Kinesin, Phosphorylation, Mitosis, 030217 neurology & neurosurgery, Function (biology), 030304 developmental biology

Abstract

Cdk1 has been found to phosphorylate the majority of its substrates in disordered regions. These phosphorylation sites do not appear to require precise positioning for their function. The mitotic kinesin-5 Cin8 was shown to be phosphoregulated at three Cdk1 sites in disordered loops within its catalytic motor domain. Here, we examined the flexibility of Cin8 phosphoregulation by analyzing the phenotypes of synthetic Cdk1-sites that were systematically generated by single amino-acid substitutions, starting from a phosphodeficient variant of Cin8. Out of 29 synthetic Cdk1 sites that we created, eight were non-functional; 19 were neutral, similar to the phosphodeficient variant; and two gave rise to phosphorylation-dependent spindle phenotypes. Of these two, one site resulted in novel phosphoregulation, and only one site, immediately adjacent to a native Cdk1 site, produced phosphoregulation similar to wild-type. This study shows that, while the gain of a single phosphorylation site can confer regulation and modulate the dynamics of the spindle, to achieve optimal regulation of a mitotic kinesin-5 motor protein, phosphoregulation has to be site-specific and precise.

Published

2018

8. Possible physiological role for bi-directional motility and motor clustering of the mitotic kinesin-5 Cin8

Author

Alina Goldstein, Ofer Shapira, Jawdat Al-Bassam, and Larisa Gheber

Subjects

0301 basic medicine, 030102 biochemistry & molecular biology, Motility, Cell Biology, Biology, Antiparallel (biochemistry), Spindle pole body, Cell biology, Spindle apparatus, 03 medical and health sciences, 030104 developmental biology, Microtubule, Kinesin, Mitosis, Multipolar spindles

Abstract

The bipolar kinesin-5 Cin8 switches from minus- to plus-end-directed motility under various conditions in vitro The mechanism and physiological significance of this switch remain unknown. Here, we show that under high ionic strength conditions, Cin8 moves towards and concentrates in clusters at the minus ends of stable and dynamic microtubules. Clustering of Cin8 induces a switch from fast minus- to slow plus-end-directed motility and forms sites that capture antiparallel microtubules (MTs) and induces their sliding apart through plus-end-directed motility. In early mitotic cells with monopolar spindles, Cin8 localizes near the spindle poles at microtubule minus ends. This localization is dependent on the minus-end-directed motility of Cin8. In cells with assembled bipolar spindles, Cin8 is distributed along the spindle microtubules. We propose that minus-end-directed motility is required for Cin8 clustering near the spindle poles before spindle assembly. Cin8 clusters promote the capture of microtubules emanating from the neighboring spindle poles and mediate their antiparallel sliding. This activity is essential to maximize microtubule crosslinking before bipolar spindle assembly and to induce the initial separation of the spindle poles.

Published

2017

9. A potential physiological role for bi-directional motility and motor clustering of mitotic kinesin-5 Cin8 in yeast mitosis

Author

Ofer, Shapira, Alina, Goldstein, Jawdat, Al-Bassam, and Larisa, Gheber

Subjects

Saccharomyces cerevisiae Proteins, Spindle Pole Bodies, Movement, Kinesins, Mitosis, Saccharomyces cerevisiae, Microtubules, Models, Biological, Research Article

Abstract

The bipolar kinesin-5 Cin8 switches from minus- to plus-end-directed motility under various conditions in vitro. The mechanism and physiological significance of this switch remain unknown. Here, we show that under high ionic strength conditions, Cin8 moves towards and concentrates in clusters at the minus ends of stable and dynamic microtubules. Clustering of Cin8 induces a switch from fast minus- to slow plus-end-directed motility and forms sites that capture antiparallel microtubules (MTs) and induces their sliding apart through plus-end-directed motility. In early mitotic cells with monopolar spindles, Cin8 localizes near the spindle poles at microtubule minus ends. This localization is dependent on the minus-end-directed motility of Cin8. In cells with assembled bipolar spindles, Cin8 is distributed along the spindle microtubules. We propose that minus-end-directed motility is required for Cin8 clustering near the spindle poles before spindle assembly. Cin8 clusters promote the capture of microtubules emanating from the neighboring spindle poles and mediate their antiparallel sliding. This activity is essential to maximize microtubule crosslinking before bipolar spindle assembly and to induce the initial separation of the spindle poles.

Published

2016

10. Motile properties of the bi-directional kinesin-5 Cin8 are affected by phosphorylation in its motor domain

Author

Larisa Gheber and Ofer Shapira

Subjects

0301 basic medicine, Cyclin-dependent kinase 1, Multidisciplinary, 030102 biochemistry & molecular biology, Motility, Biology, Article, Spindle elongation, Cell biology, 03 medical and health sciences, 030104 developmental biology, Microtubule, Kinesin, Phosphorylation, Mitosis, Anaphase

Abstract

The Saccharomyces cerevisiae kinesin-5 Cin8 performs essential mitotic functions in spindle assembly and anaphase B spindle elongation. Recent work has shown that Cin8 is a bi-directional motor which moves towards the minus-end of microtubules (MTs) under high ionic strength (IS) conditions and changes directionality in low IS conditions and when bound between anti-parallel microtubules. Previous work from our laboratory has also indicated that Cin8 is differentially phosphorylated during late anaphase at cyclin-dependent kinase 1 (Cdk1)-specific sites located in its motor domain. In vivo, such phosphorylation causes Cin8 detachment from spindles and reduces the spindle elongation rate, while maintaining proper spindle morphology. To study the effect of phosphorylation on Cin8 motor function, we examined in vitro motile properties of wild type Cin8, as well as its phosphorylation using phospho-deficient and phospho-mimic variants, in a single molecule fluorescence motility assay. Analysis was performed on whole cell extracts and on purified Cin8 samples. We found that addition of negative charges in the phospho-mimic mutant weakened the MT-motor interaction, increased motor velocity and promoted minus-end-directed motility. These results indicate that phosphorylation in the catalytic domain of Cin8 regulates its motor function.

Published

2016

11. Regulation and Possible Physiological Role of BI-Directional Motility of the Kinesin-5 Cin8

Author

Alina Goldstein, Jawdat Al-Bassam, Ofer Shapira, and Larisa Gheber

Subjects

0301 basic medicine, Cyclin-dependent kinase 1, Biophysics, Motility, Biology, Spindle apparatus, Cell biology, 03 medical and health sciences, 030104 developmental biology, Microtubule, Directionality, Kinesin, Mitosis, Anaphase

Abstract

The homoterameric bipolar kinesin-5 motors perform essential functions in mitotic spindle dynamics by crosslinking and sliding apart antiparallel microtubules. S. cerevisiae cells express two kinesin-5s Cin8 and Kip1, which overlap in function. We have recently demonstrated that Cin8 and Kip1 are minus-end directed on the single-molecule level and can switch directionality under a number of conditions (Duselder et al., 2015; Fridman et al., 2013; Gerson-Gurwitz et al., 2011). The mechanism of this directionality switch and its physiological significance remain unclear. We have also demonstrated that Cin8 is differentially phosphorylated during late anaphase at three cyclin-dependent kinase 1 (Cdk1) sites located in its motor domain. This phosphorylation regulates Cin8 activity during anaphase (Avunie-Masala et al., 2011), but its mechanism remains unclear.Here we examined the in vitro motile properties and in vivo functions of Cin8 by TIRF microscopy and live-cell imaging. We found that addition of negative charge in a phospho-mimic Cin8 mutant weakens the MT-motor interaction and regulates the motile properties and directionality of Cin8. We also found that of the three Cdk1 sites in the catalytic domain of Cin8, the S277 site contributes the most to regulation of Cin8 localization and function during anaphase. Finally, we found that in vitro under high ionic strength conditions, Cin8 not only moves to- but also clusters at the minus-end of the MTs. This clustering causes Cin8 to reverse its directionality from fast minus- to slow plus-end directed motility. Clustering of Cin8 at the minus-end of the MTs serves as a primary site for capturing and antiparallel sliding of MTs. Based on these results, we propose a revised model for activity of Cin8 during mitosis and propose a physiological role for its minus-end directionality.

Published

2016

12. Regulation of bi-directional movement of single kinesin-5 Cin8 molecules

Author

Christina Thiede, Adina Gerson-Gurwitz, Vladimir Fridman, Christoph F. Schmidt, and Larisa Gheber

Subjects

mitosis, Short Communication, Saccharomyces cerevisiae, Motility, Nanotechnology, macromolecular substances, Cell Biology, General Medicine, Saccharomyces cerevisiae Cin8, Biology, biology.organism_classification, Spindle apparatus, microtubules, Coupling (electronics), kinesin-5, Structural Biology, Microtubule, Biophysics, Directionality, Kinesin, kinesin directionality, Mitosis

Abstract

Kinesin-5 mechanoenzymes drive mitotic spindle dynamics as slow, processive microtubule (MT)-plus-end directed motors. Surprisingly, the Saccharomyces cerevisiae kinesin-5 Cin8 was recently found to be bi-directional: it can move processively in both directions on MTs. Two hypotheses have been suggested for the mechanism of the directionality switch: (1) single molecules of Cin8 are intrinsically minus-end directed, but mechanical coupling between two or more motors triggers the switch; (2) a single motor can switch direction, and "cargo binding" i.e., binding between two MTs triggers the switch to plus-end motility. Single-molecule fluorescence data we published recently, and augment here, favor hypothesis (2). In low-ionic-strength conditions, single molecules of Cin8 move in both minus- and plus-end directions. Fluorescence photo bleaching data rule out aggregation of Cin8 while they move in the plus and in the minus direction. The evidence thus points toward cargo regulation of directionality, which is likely to be related to cargo regulation in other kinesins. The molecular mechanisms of this regulation, however, remain to be elucidated.

Published

2012

13. Phospho-regulation of kinesin-5 during anaphase spindle elongation

Author

Vladimir Fridman, Adina Gerson-Gurwitz, Larisa Gheber, Mart Loog, Yael Nissenkorn, Rachel Avunie-Masala, Arieh Zaritsky, Mardo Kõivomägi, Natalia Movshovich, and M. Andrew Hoyt

Subjects

Cdk1, Saccharomyces cerevisiae Proteins, Kinesins, Mitosis, Saccharomyces cerevisiae, Spindle Apparatus, Biology, Microtubules, Spindle pole body, Spindle elongation, 03 medical and health sciences, Short Reports, CDC2 Protein Kinase, Phosphorylation, 030304 developmental biology, Anaphase, 0303 health sciences, Kinetochore, 030302 biochemistry & molecular biology, Kinesin-5, Cell Biology, Cin8, Cell biology, Spindle apparatus, Protein Transport, Spindle checkpoint, Securin, Multipolar spindles

Abstract

The kinesin-5 Saccharomyces cerevisiae homologue Cin8 is shown here to be differentially phosphorylated during late anaphase at Cdk1-specific sites located in its motor domain. Wild-type Cin8 binds to the early-anaphase spindles and detaches from the spindles at late anaphase, whereas the phosphorylation-deficient Cin8-3A mutant protein remains attached to a larger region of the spindle and spindle poles for prolonged periods. This localization of Cin8-3A causes faster spindle elongation and longer anaphase spindles, which have aberrant morphology. By contrast, the phospho-mimic Cin8-3D mutant exhibits reduced binding to the spindles. In the absence of the kinesin-5 homologue Kip1, cells expressing Cin8-3D exhibit spindle assembly defects and are not viable at 37°C as a result of spindle collapse. We propose that dephosphorylation of Cin8 promotes its binding to the spindle microtubules before the onset of anaphase. In mid to late anaphase, phosphorylation of Cin8 causes its detachment from the spindles, which reduces the spindle elongation rate and aids in maintaining spindle morphology.

Published

2011

14. Differential Phosphorylation in the Motor Domain of Mitotic Kinesin-5 Cin8 Regulates its Functions In Vivo

Author

Ervin Valk, Alina Goldstein, Mardo Kõivomägi, Ofer Shapira, Darya Goldman, Mart Loog, Nurit Siegler, and Larisa Gheber

Subjects

Motor domain, Chemistry, In vivo, Biophysics, Phosphorylation, Kinesin, Mitosis, Differential (mathematics), Cell biology

Published

2018

15. Phosphorylation Regulates the Motile Properties of a Mitotic Kinesin

Author

Ofer Shapira and Larisa Gheber

Subjects

Microtubule, Biophysics, Motility, Phosphorylation, Kinesin, Biology, Mitosis, Spindle elongation, Anaphase, Cell biology, Spindle apparatus

Abstract

Saccharomyces cerevisiaes Cin8, a member of the kinesin-5 family of motors, performs important functions in mitotic spindle dynamics such as spindle assembly and anaphase spindle elongation. Resent work has shown that Cin8 is a bidirectional motor and moves in vitro towards the minus-end of microtubules (MTs) and changes directionality as a function on ionic strength conditions and MT binding geometry (Gerson-Gurwitz et al., 2011). Previous work from our laboratory had also indicated that Cin8 is differentially phosphorylated during late anaphase at three cyclin-dependent kinase 1 (Cdk1) specific sites located in its motor domain. In vivo, this phosphorylation causes Cin8 detachment from the spindles, reduces spindle elongation rate and aids in maintaining proper spindle morphology (Avunie-Masala et al., 2011).Here, we examined the in vitro motile properties of Cin8 by a single-molecule fluorescence motility assay. To study the effect of phosphorylation, we examined the activity of phosphorylation-deficient and phosphorylation-mimic mutant of Cin8. The analysis was done in whole cell extracts as well as on purified Cin8 samples. We found that addition of negative charge in the phospho-mimic mutant weakens the MT-motor interaction and alters the motile properties of Cin8. These results indicate that phosphorylation of Cin8 in the catalytic domain, regulates its motor function.

Published

2015

16. Mitotic slippage and expression of survivin are linked to differential sensitivity of human cancer cell-lines to the Kinesin-5 inhibitor monastrol

Author

Hila Asraf, Rachel Avunie-Masala, Larisa Gheber, and Michal Hershfinkel

Subjects

Small interfering RNA, Survivin, Blotting, Western, Kinesins, Mitosis, lcsh:Medicine, Apoptosis, Spindle Apparatus, Biology, Real-Time Polymerase Chain Reaction, Inhibitor of Apoptosis Proteins, chemistry.chemical_compound, Neoplasms, Tumor Cells, Cultured, Gene silencing, Humans, Viability assay, RNA, Messenger, RNA, Small Interfering, lcsh:Science, Cell Proliferation, Multidisciplinary, Reverse Transcriptase Polymerase Chain Reaction, Cell Cycle, lcsh:R, Thiones, Cell cycle, Cell biology, Spindle apparatus, Monastrol, Pyrimidines, chemistry, Drug Resistance, Neoplasm, lcsh:Q, Research Article

Abstract

The mitotic Kinesin-5 motor proteins crosslink and slide apart antiparallel spindle microtubules, thus performing essential functions in mitotic spindle dynamics. Specific inhibition of their function by monastrol-like small molecules has been examined in clinical trials as anticancer treatment, with only partial success. Thus, strategies that improve the efficiency of monastrol-like anticancer drugs are required. In the current study, we examined the link between sensitivity to monastrol and occurrence of mitotic slippage in several human cell-lines. We found that the rank of sensitivity to monastrol, from most sensitive to least sensitive, is: AGS > HepG2 > Lovo > Du145 ≥ HT29. We show correlation between the sensitivity of a particular cell-line to monastrol and the tendency of the same cell-line to undergo mitotic slippage. We also found that in the monastrol resistant HT29 cells, prolonged monastrol treatments increase mRNA and protein levels of the chromosomal passenger protein survivin. In contrast, survivin levels are not increased by this treatment in the monastrol-sensitive AGS cells. We further show that over-expression of survivin in the monastrol-sensitive AGS cells reduces mitotic slippage and increases resistance to monastrol. Finally, we show that during short exposure to monastrol, Si RNA silencing of survivin expression reduces cell viability in both AGS and HT29 cells. Our data suggest that the efficiency of anti-cancer treatment with specific kinesin-5 inhibitors may be improved by modulation of expression levels of survivin.

Published

2015

17. Kinesin-5 Kip1 is a bi-directional motor that stabilizes microtubules and tracks their plus-ends in vivo

Author

Vladimir Fridman, Christoph F. Schmidt, Stefan Lakämper, Larisa Gheber, Adina Gerson-Gurwitz, Natalia Movshovich, and Ofer Shapira

Subjects

Cell Nucleus, 0303 health sciences, Saccharomyces cerevisiae Proteins, Mitotic spindle midzone, Kinesins, Mitosis, Saccharomyces cerevisiae, Cell Biology, Biology, Microtubules, Spindle pole body, Spindle apparatus, Cell biology, Motor protein, 03 medical and health sciences, 0302 clinical medicine, Microtubule, Proliferating Cell Nuclear Antigen, Microtubule Proteins, Kinesin, 030217 neurology & neurosurgery, 030304 developmental biology, Anaphase

Abstract

In this study, we examined the anaphase functions of the S. cerevisiae kinesin-5 homolog Kip1. We show that Kip1 is attached to the mitotic spindle midzone during late anaphase. This attachment is essential to stabilize interpolar microtubule (iMTs) plus-ends. By detailed examination of iMT dynamics we show that at the end of anaphase, iMTs depolymerize in two stages: during the first stage, one pair of anti-parallel iMTs depolymerizes at a velocity of 7.7 µm/minute; during the second stage, ∼90 seconds later, the remaining pair of iMTs depolymerizes at a slower velocity of 5.4 µm/minute. We show that upon the second depolymerization stage, which coincides with spindle breakdown, Kip1 follows the plus-ends of depolymerizing iMTs and translocates toward the spindle poles. This movement is independent of mitotic microtubule motor proteins or the major plus-end binding or tracking proteins. In addition, we show that Kip1 processively tracks the plus-ends of growing and shrinking MTs, both inside and outside the nucleus. The plus-end tracking activity of Kip1 requires its catalytic motor function, because a rigor mutant of Kip1 does not exhibit this activity. Finally, we show that Kip1 is a bi-directional motor: in vitro, at high ionic strength conditions, single Kip1 molecules move processively in the minus-end direction of the MTs, whereas in a multi-motor gliding assay, Kip1 is plus-end directed. The bi-directionality and plus-end tracking activity of Kip1, properties revealed here for the first time, allow Kip1 to perform its multiple functions in mitotic spindle dynamics and to partition the 2-micron plasmid.

Published

2013

18. Midzone organization restricts interpolar microtubule plus-end dynamics during spindle elongation

Author

Natalia Movshovich, Adina Gerson-Gurwitz, Larisa Gheber, Martin Kupiec, and Vladimir Fridman

Subjects

Saccharomyces cerevisiae Proteins, Microtubule-associated protein, Green Fluorescent Proteins, Scientific Report, Kinesins, Saccharomyces cerevisiae, Spindle Apparatus, Biology, Biochemistry, Microtubules, Spindle elongation, Microtubule, Tubulin, Genetics, cardiovascular diseases, Molecular Biology, Mitosis, Anaphase, Fluorescence recovery after photobleaching, musculoskeletal system, Microtubule plus-end, Cell biology, cardiovascular system, Kinesin, Schizosaccharomyces pombe Proteins, Microtubule-Associated Proteins, Fluorescence Recovery After Photobleaching

Abstract

To study the dynamics of interpolar microtubules (iMTs) in Saccharomyces cerevisiae cells, we photobleached a considerable portion of the middle region of anaphase spindles in cells expressing tubulin-green fluorescent protein (GFP) and followed fluorescence recovery at the iMT plus-ends. We found that during anaphase, iMTs show phases of fast growth and shrinkage that are restricted to the iMT plus-ends. Our data indicate that iMT plus-end dynamics are regulated during mitosis, as fluorescence recovery was faster in intermediate anaphase (30 s) compared with long (100 s) and pre-anaphase (80 s) spindles. We also observed that deletion of Cin8, a microtubule-crosslinking kinesin-5 motor protein, reduced the recovery rate in anaphase spindles, indicating that Cin8 contributes to the destabilization of iMT plus-ends. Finally, we show that in cells lacking the midzone organizing protein Ase1, iMTs are highly dynamic and are exchangeable throughout most of their length, indicating that midzone organization is essential for restricting iMT dynamics.

Published

2008

19. Homotetrameric form of Cin8p, a Saccharomyces cerevisiae kinesin-5 motor, is essential for its in vivo function

Author

M. Andrew Hoyt, Emily R. Hildebrandt, Tami J. Kingsbury, and Larisa Gheber

Subjects

Saccharomyces cerevisiae Proteins, Kinesins, Mitosis, Saccharomyces cerevisiae, Biology, Biochemistry, Microtubules, Spindle elongation, Protein Structure, Secondary, Motor protein, Microtubule, Animals, Protein Isoforms, Protein Structure, Quaternary, Molecular Biology, Anaphase, Genetics, Molecular Motor Proteins, Cell Biology, Spindle apparatus, Cell biology, Phenotype, Mutation, Kinesin, Spindle localization, Microtubule-Associated Proteins

Abstract

Kinesin-5 motor proteins are evolutionarily conserved and perform essential roles in mitotic spindle assembly and spindle elongation during anaphase. Previous studies demonstrated a specialized homotetrameric structure with two pairs of catalytic domains, one at each end of a dumbbell-shaped molecule. This suggests that they perform their spindle roles by cross-linking and sliding antiparallel spindle microtubules. However, the exact kinesin-5 sequence elements that are important for formation of the tetrameric complexes have not yet been identified. In addition, it has not been demonstrated that the homotetrameric form of these proteins is essential for their biological functions. Thus, we investigated a series of Saccharomyces cerevisiae Cin8p truncations and internal deletions, in order to identify structural elements in the Cin8p sequence that are required for Cin8p functionality, spindle localization, and multimerization. We found that all variants of Cin8p that are functional in vivo form tetrameric complexes. The first coiled-coil domain in the stalk of Cin8p, a feature that is shared by all kinesin-5 homologues, is required for its dimerization, and sequences in the last part of the stalk, specifically those likely involved in coiled-coil formation, are required for Cin8p tetramerization. We also found that dimeric forms of Cin8p that are nonfunctional in vivo can nonetheless bind to microtubules. These findings suggest that binding of microtubules is not sufficient for the functionality of Cin8p and that microtubule cross-linking by the tetrameric complex is essential for Cin8p mitotic functions.

Published

2006

20. Differential effects of monastrol in two human cell lines

Author

I. Leizerman, Moshe Elkabets, Rachel Avunie-Masala, Alexander Fich, and Larisa Gheber

Subjects

G2 Phase, Paclitaxel, Kinesins, Mitosis, Apoptosis, Biology, Cleavage (embryo), Microtubules, Cellular and Molecular Neuroscience, chemistry.chemical_compound, HT29 Cells, Stomach Neoplasms, Humans, Molecular Biology, Pharmacology, Cell growth, Thiones, Cell Biology, Antineoplastic Agents, Phytogenic, Cell biology, Spindle apparatus, Pyrimidines, Monastrol, chemistry, Cell culture, Colonic Neoplasms, Molecular Medicine, Intracellular

Abstract

The kinesin-related protein HsEg5 plays essential roles in mitotic spindle dynamics. Although inhibition of HsEg5 has been suggested as an aid in cancer treatment, the effects of such inhibition on human cells have not been characterized. Here we studied the effects of monastrol, an allosteric HsEg5 inhibitor, on AGS and HT29 cell lines and compared them to those of taxol. While both cell lines were similarly sensitive to taxol, AGS cells were more sensitive to monastrol. The differences in sensitivity were determined by the degree of inhibitory effect on cell proliferation, reversibility of monastrol-induced G2/M arrest, intracellular phenotypes and induction of apoptosis. In both cell lines, monastrol-induced apoptosis was accompanied by mitochondrial membrane depolarization and poly-ADP-ribose polymerase 1 cleavage. In AGS, but not HT29 cells, monastrol-induced apoptosis involved a prominent cleavage of procaspases 8 and 3. While in AGS cells, monastrol induced the formation of symmetric microtubule asters only, in HT29 cells, asymmetric asters were also formed, which may be related to specific HsEg5 functions in HT29 cells.

Published

2004

21. Novel roles for saccharomyces cerevisiae mitotic spindle motors

Author

M. Andrew Hoyt, Frank R. Cottingham, Larisa Gheber, and Dana L. Miller

Subjects

Saccharomyces cerevisiae Proteins, Dynein, Kinesins, Mitosis, Saccharomyces cerevisiae, Biology, kinesin, Spindle pole body, Motor protein, Fungal Proteins, microtubules, 03 medical and health sciences, Microtubule, 030304 developmental biology, 0303 health sciences, dynein, Kinetochore, Molecular Motor Proteins, motor proteins, 030302 biochemistry & molecular biology, Dyneins, Microtubule organizing center, Cell Biology, Spindle apparatus, Cell biology, Spindle checkpoint, mitotic spindle, Original Article, Microtubule-Associated Proteins

Abstract

The single cytoplasmic dynein and five of the six kinesin-related proteins encoded by Saccharomyces cerevisiae participate in mitotic spindle function. Some of the motors operate within the nucleus to assemble and elongate the bipolar spindle. Others operate on the cytoplasmic microtubules to effect spindle and nuclear positioning within the cell. This study reveals that kinesin-related Kar3p and Kip3p are unique in that they perform roles both inside and outside the nucleus. Kar3p, like Kip3p, was found to be required for spindle positioning in the absence of dynein. The spindle positioning role of Kar3p is performed in concert with the Cik1p accessory factor, but not the homologous Vik1p. Kar3p and Kip3p were also found to overlap for a function essential for the structural integrity of the bipolar spindle. The cytoplasmic and nuclear roles of both these motors could be partially substituted for by the microtubule-destabilizing agent benomyl, suggesting that these motors perform an essential microtubule-destabilizing function. In addition, we found that yeast cell viability could be supported by as few as two microtubule-based motors: the BimC-type kinesin Cin8p, required for spindle structure, paired with either Kar3p or Kip3p, required for both spindle structure and positioning.

Published

1999

22. Mitotic Functions and Motile Properties of the S. cerevisiae Kinesin-5 motors

Author

Vladimir Fridman, Christoph F. Schmidt, Stefan Lakämper, Adina Gerson-Gurwitz, Larisa Gheber, Christina Thiede, Maria Podolskaya, and Movshovich Natalia

Subjects

Spindle checkpoint, Kinetochore, Biophysics, Molecular motor, Biology, Metaphase, Mitosis, Spindle pole body, Spindle apparatus, Anaphase, Cell biology

Abstract

Mitotic chromosome segregation is mediated by mitotic spindle, a highly dynamic microtubule-based structure, which undergoes a distinct set of morphological changes in each mitotic cycle. Major factors that contribute to spindle morphogenesis are microtubule (MT) plus-end dynamics and function of molecular motors from the Kinesin-5 family. Kinesin-5 family members are conserved, homotetrameric motors with two catalytic domains located on opposite sides of the active complex. This special architecture enables these motors to crosslink and slide anti-parallel MTs originating from opposite spindle poles and thereby perform their essential functions in mitotic spindle morphogenesis. It was recently shown that Kinesin-5 motors affect anaphase spindle symmetry and midzone organization (1). S. cerevisiae cells express two Kinesin-5 homologues, Cin8p and Kip1p that overlap in function during spindle assembly, metaphase and anaphase B and at least one of them need to be expressed for viability. So far, the extent of redundancy between these two Kinesin-5 proteins and their motile properties in vitro have not been thoroughly investigated.In the present study, we use high temporal and spatial resolution imaging and FRAP to characterize interpolar MT (iMT) plus-end dynamics during spindle morphogenesis in S. cerevisiae cells expressing tubulin-GFP(2). This approach allowed us to study the role of the major midzone organizing protein Ase1(2) in controlling iMT plus-end dynamics and to compare between the effects of Cin8 and Kip1 on these dynamics during anaphase. In addition, in order to understand in vivo functions of the Kinesin-5 Kip1, we characterized its motile properties in single-molecule fluorescence motility assay. Results from this assay will be presented.(1) Movshovich N, et al. J Cell Sci. 2008; 121:2529.(2) Fridman V, et al. EMBO Rep. 2009; 10:387.∗ Supported by the Lower-Saxony collaboration grant between BGU and GAUG

Published

2011