Overlap microtubules link sister k-fibres and balance the forces on bi-oriented kinetochores

Janko Kajtez; Anastasia Solomatina; Maja Novak; Bruno Polak; Kruno Vukušić; Jonas Rüdiger; Gheorghe Cojoc; Ana Milas; Ivana Šumanovac Šestak; Patrik Risteski; Federica Tavano; Anna H. Klemm; Emanuele Roscioli; Julie Welburn; Daniela Cimini; Matko Glunčić; Nenad Pavin; Iva M. Tolić

doi:10.1038/ncomms10298

Overlap microtubules link sister k-fibres and balance the forces on bi-oriented kinetochores

Janko Kajtez, Anastasia Solomatina, Maja Novak, Bruno Polak, Kruno Vukušić, Jonas Rüdiger, Gheorghe Cojoc, Ana Milas, Ivana Šumanovac Šestak, Patrik Risteski, Federica Tavano, Anna H. Klemm, Emanuele Roscioli, Julie Welburn, Daniela Cimini, Matko Glunčić, Nenad Pavin^*, Iva M. Tolić

^*Corresponding author for this work

School of Biological Sciences

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Abstract / Description of output

During metaphase, forces on kinetochores are exerted by k-fibres, bundles of microtubules that end at the kinetochore. Interestingly, non-kinetochore microtubules have been observed between sister kinetochores, but their function is unknown. Here we show by laser-cutting of a k-fibre in HeLa and PtK1 cells that a bundle of non-kinetochore microtubules, which we term 'bridging fibre', bridges sister k-fibres and balances the interkinetochore tension. We found PRC1 and EB3 in the bridging fibre, suggesting that it consists of antiparallel dynamic microtubules. By using a theoretical model that includes a bridging fibre, we show that the forces at the pole and at the kinetochore depend on the bridging fibre thickness. Moreover, our theory and experiments show larger relaxation of the interkinetochore distance for cuts closer to kinetochores. We conclude that the bridging fibre, by linking sister k-fibres, withstands the tension between sister kinetochores and enables the spindle to obtain a curved shape.

Original language	English
Article number	10298
Journal	Nature Communications
Volume	7
DOIs	https://doi.org/10.1038/ncomms10298
Publication status	Published - 5 Jan 2016

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10.1038/ncomms10298

Overlap microtubles link sister k-fibres and balance the fores on bi-oriented kinetochores
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Kajtez, J., Solomatina, A., Novak, M., Polak, B., Vukušić, K., Rüdiger, J., Cojoc, G., Milas, A., Šumanovac Šestak, I., Risteski, P., Tavano, F., Klemm, A. H., Roscioli, E., Welburn, J., Cimini, D., Glunčić, M., Pavin, N., & Tolić, I. M. (2016). Overlap microtubules link sister k-fibres and balance the forces on bi-oriented kinetochores. Nature Communications, 7, Article 10298. https://doi.org/10.1038/ncomms10298

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title = "Overlap microtubules link sister k-fibres and balance the forces on bi-oriented kinetochores",

abstract = "During metaphase, forces on kinetochores are exerted by k-fibres, bundles of microtubules that end at the kinetochore. Interestingly, non-kinetochore microtubules have been observed between sister kinetochores, but their function is unknown. Here we show by laser-cutting of a k-fibre in HeLa and PtK1 cells that a bundle of non-kinetochore microtubules, which we term 'bridging fibre', bridges sister k-fibres and balances the interkinetochore tension. We found PRC1 and EB3 in the bridging fibre, suggesting that it consists of antiparallel dynamic microtubules. By using a theoretical model that includes a bridging fibre, we show that the forces at the pole and at the kinetochore depend on the bridging fibre thickness. Moreover, our theory and experiments show larger relaxation of the interkinetochore distance for cuts closer to kinetochores. We conclude that the bridging fibre, by linking sister k-fibres, withstands the tension between sister kinetochores and enables the spindle to obtain a curved shape.",

author = "Janko Kajtez and Anastasia Solomatina and Maja Novak and Bruno Polak and Kruno Vuku{\v s}i{\'c} and Jonas R{\"u}diger and Gheorghe Cojoc and Ana Milas and {{\v S}umanovac {\v S}estak}, Ivana and Patrik Risteski and Federica Tavano and Klemm, {Anna H.} and Emanuele Roscioli and Julie Welburn and Daniela Cimini and Matko Glun{\v c}i{\'c} and Nenad Pavin and Toli{\'c}, {Iva M.}",

year = "2016",

month = jan,

day = "5",

doi = "10.1038/ncomms10298",

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Kajtez, J, Solomatina, A, Novak, M, Polak, B, Vukušić, K, Rüdiger, J, Cojoc, G, Milas, A, Šumanovac Šestak, I, Risteski, P, Tavano, F, Klemm, AH, Roscioli, E, Welburn, J, Cimini, D, Glunčić, M, Pavin, N & Tolić, IM 2016, 'Overlap microtubules link sister k-fibres and balance the forces on bi-oriented kinetochores', Nature Communications, vol. 7, 10298. https://doi.org/10.1038/ncomms10298

TY - JOUR

T1 - Overlap microtubules link sister k-fibres and balance the forces on bi-oriented kinetochores

AU - Kajtez, Janko

AU - Solomatina, Anastasia

AU - Novak, Maja

AU - Polak, Bruno

AU - Vukušić, Kruno

AU - Rüdiger, Jonas

AU - Cojoc, Gheorghe

AU - Milas, Ana

AU - Šumanovac Šestak, Ivana

AU - Risteski, Patrik

AU - Tavano, Federica

AU - Klemm, Anna H.

AU - Roscioli, Emanuele

AU - Welburn, Julie

AU - Cimini, Daniela

AU - Glunčić, Matko

AU - Pavin, Nenad

AU - Tolić, Iva M.

PY - 2016/1/5

Y1 - 2016/1/5

N2 - During metaphase, forces on kinetochores are exerted by k-fibres, bundles of microtubules that end at the kinetochore. Interestingly, non-kinetochore microtubules have been observed between sister kinetochores, but their function is unknown. Here we show by laser-cutting of a k-fibre in HeLa and PtK1 cells that a bundle of non-kinetochore microtubules, which we term 'bridging fibre', bridges sister k-fibres and balances the interkinetochore tension. We found PRC1 and EB3 in the bridging fibre, suggesting that it consists of antiparallel dynamic microtubules. By using a theoretical model that includes a bridging fibre, we show that the forces at the pole and at the kinetochore depend on the bridging fibre thickness. Moreover, our theory and experiments show larger relaxation of the interkinetochore distance for cuts closer to kinetochores. We conclude that the bridging fibre, by linking sister k-fibres, withstands the tension between sister kinetochores and enables the spindle to obtain a curved shape.

AB - During metaphase, forces on kinetochores are exerted by k-fibres, bundles of microtubules that end at the kinetochore. Interestingly, non-kinetochore microtubules have been observed between sister kinetochores, but their function is unknown. Here we show by laser-cutting of a k-fibre in HeLa and PtK1 cells that a bundle of non-kinetochore microtubules, which we term 'bridging fibre', bridges sister k-fibres and balances the interkinetochore tension. We found PRC1 and EB3 in the bridging fibre, suggesting that it consists of antiparallel dynamic microtubules. By using a theoretical model that includes a bridging fibre, we show that the forces at the pole and at the kinetochore depend on the bridging fibre thickness. Moreover, our theory and experiments show larger relaxation of the interkinetochore distance for cuts closer to kinetochores. We conclude that the bridging fibre, by linking sister k-fibres, withstands the tension between sister kinetochores and enables the spindle to obtain a curved shape.

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U2 - 10.1038/ncomms10298

DO - 10.1038/ncomms10298

M3 - Article

AN - SCOPUS:84953212339

SN - 2041-1723

VL - 7

JO - Nature Communications

JF - Nature Communications

M1 - 10298

ER -

Overlap microtubules link sister k-fibres and balance the forces on bi-oriented kinetochores

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Overlap microtubules link sister k-fibres and balance the forces on bi-oriented kinetochores

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