Yaqing Du scite author profile

Motility is a fundamentally important property of most members of the kinesin superfamily, but a rare subset of kinesins are also able to alter microtubule dynamics. At kinetochore-microtubule plus ends, the kinesin-8 family member Kif18A is essential to align mitotic chromosomes at the spindle equator during cell division, but how it accomplishes this function is unclear. We report here that Kif18A is a plus-end-directed motor that inhibits the polymerization dynamics of microtubule plus ends without destabilizing them, distinguishing Kif18A from the budding yeast ortholog Kip3. In interphase cells, Kif18A uses this activity to reduce the overall dynamicity of microtubule plus ends and effectively constrains the distance over which plus ends grow and shrink. Our findings suggest that kinesin-8 family members have developed biochemically distinct activities throughout evolution and have implications for how Kif18A affects kinetochore-microtubule plus-end dynamics during mitosis in animal cells.

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A Tethering Mechanism Controls the Processivity and Kinetochore-Microtubule Plus-End Enrichment of the Kinesin-8 Kif18A

Stumpff

et al. 2011

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Summary Metaphase chromosome positioning depends on Kif18A, a kinesin-8 that accumulates at and suppresses the dynamics of K-MT plus ends. By engineering Kif18A mutants that suppress MT dynamics but fail to concentrate at K-MT plus-ends, we identify a mechanism that allows Kif18A to accumulate at K-MT plus ends to a level required to suppress chromosome movements. Enrichment of Kif18A at K-MT plus-ends depends on its C-terminal tail domain, while the ability of Kif18A to suppress MT growth is conferred by the N-terminal motor domain. The Kif18A tail contains a second MT-binding domain that diffuses along the MT lattice, suggesting that it tethers the motor to the MT track. Consistently, the tail enhances Kif18A processivity and is crucial for it to accumulate at K-MT plus-ends. The heightened processivity of Kif18A, conferred by its tail domain, thus promotes concentration of Kif18A at K-MT plus-ends, where it suppresses their dynamics to control chromosome movements.

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DNA Binding of Centromere Protein C (CENPC) Is Stabilized by Single-Stranded RNA

2010

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Centromeres are the attachment points between the genome and the cytoskeleton: centromeres bind to kinetochores, which in turn bind to spindles and move chromosomes. Paradoxically, the DNA sequence of centromeres has little or no role in perpetuating kinetochores. As such they are striking examples of genetic information being transmitted in a manner that is independent of DNA sequence (epigenetically). It has been found that RNA transcribed from centromeres remains bound within the kinetochore region, and this local population of RNA is thought to be part of the epigenetic marking system. Here we carried out a genetic and biochemical study of maize CENPC, a key inner kinetochore protein. We show that DNA binding is conferred by a localized region 122 amino acids long, and that the DNA-binding reaction is exquisitely sensitive to single-stranded RNA. Long, single-stranded nucleic acids strongly promote the binding of CENPC to DNA, and the types of RNAs that stabilize DNA binding match in size and character the RNAs present on kinetochores in vivo. Removal or replacement of the binding module with HIV integrase binding domain causes a partial delocalization of CENPC in vivo. The data suggest that centromeric RNA helps to recruit CENPC to the inner kinetochore by altering its DNA binding characteristics.

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The Chlamydia Effector Chlamydial Outer Protein N (CopN) Sequesters Tubulin and Prevents Microtubule Assembly

Archuleta

English

et al. 2011

Journal of Biological Chemistry

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Chlamydia species are obligate intracellular pathogens that utilize a type three secretion system to manipulate host cell processes. Genetic manipulations are currently not possible in Chlamydia, necessitating study of effector proteins in heterologous expression systems and severely complicating efforts to relate molecular strategies used by Chlamydia to the biochemical activities of effector proteins. CopN is a chlamydial type three secretion effector that is essential for virulence. Heterologous expression of CopN in cells results in loss of microtubule spindles and metaphase plate formation and causes mitotic arrest. CopN is a multidomain protein with similarity to type three secretion system "plug" proteins from other organisms but has functionally diverged such that it also functions as an effector protein. We show that CopN binds directly to ␣␤-tubulin but not to microtubules (MTs). Furthermore, CopN inhibits tubulin polymerization by sequestering free ␣␤-tubulin, similar to one of the mechanisms utilized by stathmin. Although CopN and stathmin share no detectable sequence identity, both influence MT formation by sequestration of ␣␤-tubulin. CopN displaces stathmin from preformed stathmin-tubulin complexes, indicating that the proteins bind overlapping sites on tubulin. CopN is the first bacterial effector shown to disrupt MT formation directly. This recognition affords a mechanistic understanding of a strategy Chlamydia species use to manipulate the host cell cycle.Chlamydia species, the causative agents of a range of human diseases, including genital, ocular, and respiratory infection (3, 14 -16), are obligate intracellular pathogens with a biphasic life cycle consisting of metabolically inactive elementary bodies and metabolically active reticulate bodies (17). Infection involves attachment and cellular uptake of elementary bodies and subsequent differentiation into reticulate bodies. The reticulate bodies remain in endosome-derived membrane vacuoles termed "inclusions," which migrate to the microtubule-organizing center in a dynein-dependent process (18 -20). After

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Biased Brownian motion as a mechanism to facilitate nanometer-scale exploration of the microtubule plus end by a kinesin-8

Shin

Collier

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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Kinesin-8s are plus-end-directed motors that negatively regulate microtubule (MT) length. Well-characterized members of this subfamily (Kip3, Kif18A) exhibit two important properties: (i) They are "ultraprocessive," a feature enabled by a second MT-binding site that tethers the motors to a MT track, and (ii) they dissociate infrequently from the plus end. Together, these characteristics combined with their plus-end motility cause Kip3 and Kif18A to enrich preferentially at the plus ends of long MTs, promoting MT catastrophes or pausing. Kif18B, an understudied human kinesin-8, also limits MT growth during mitosis. In contrast to Kif18A and Kip3, localization of Kif18B to plus ends relies on binding to the plus-end tracking protein EB1, making the relationship between its potential plus-end-directed motility and plus-end accumulation unclear. Using single-molecule assays, we show that Kif18B is only modestly processive and that the motor switches frequently between directed and diffusive modes of motility. Diffusion is promoted by the tail domain, which also contains a second MT-binding site that decreases the off rate of the motor from the MT lattice. In cells, Kif18B concentrates at the extreme tip of a subset of MTs, superseding EB1. Our data demonstrate that kinesin-8 motors use diverse design principles to target MT plus ends, which likely target them to the plus ends of distinct MT subpopulations in the mitotic spindle.kinesin-8 | Kif18B | microtubule | EB1 | mitosis

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Yaqing Du

The Kinesin-8 Kif18A Dampens Microtubule Plus-End Dynamics

A Tethering Mechanism Controls the Processivity and Kinetochore-Microtubule Plus-End Enrichment of the Kinesin-8 Kif18A

DNA Binding of Centromere Protein C (CENPC) Is Stabilized by Single-Stranded RNA

The Chlamydia Effector Chlamydial Outer Protein N (CopN) Sequesters Tubulin and Prevents Microtubule Assembly

Biased Brownian motion as a mechanism to facilitate nanometer-scale exploration of the microtubule plus end by a kinesin-8

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