SUMMARY
Kinetochores couple chromosomes to the assembling and disassembling tips of microtubules, a dynamic behavior that is fundamental to mitosis in all eukaryotes but poorly understood. Genetic, biochemical and structural studies implicate the Ndc80 complex as a direct point of contact between kinetochores and microtubules, but these approaches provide only a static view. Here, using techniques for manipulating and tracking individual molecules in vitro, we demonstrate that the Ndc80 complex is capable of forming the dynamic, load-bearing attachments to assembling and disassembling tips required for coupling in vivo. We also establish that Ndc80-based coupling likely occurs through a biased diffusion mechanism, and that this activity is conserved from yeast to humans. Our findings demonstrate how an ensemble of Ndc80 complexes may provide a ‘slip clutch’ that allows the kinetochore to maintain a load-bearing tip attachment during both microtubule assembly and disassembly.
The Dam1 complex, regulated by aurora B phosphorylation, confers a more stable microtubule association for the Ndc80 complex at kinetochores (see also related paper by Lampert et al. in this issue).
The kinesin-13, MCAK, is a critical regulator of microtubule dynamics in eukaryotic cells1. We have functionally dissected the structural features responsible for MCAK’s potent microtubule depolymerization activity. MCAK’s positively charged neck enhances its delivery to microtubule ends, not by tethering the molecule to microtubules during diffusion, as commonly thought, but by catalyzing the association of MCAK to microtubules. On the other hand, this same positively charged neck slightly diminishes MCAK’s ability to remove tubulin subunits once at the microtubule end. Conversely, dimerization reduces MCAK delivery but improves MCAK’s ability to remove tubulin subunits. The reported kinetics for these events predict a non-specific binding mechanism that may represent a paradigm for the diffusive interaction of many microtubule binding proteins.
Summary
Microtubule based motility is often thought of as specifically referring to the directed stepping of microtubule based motors such as kinesin or dynein. However microtubule lattice diffusion (also known as diffusional motility) provides a second mode of transport that is shared by a much broader class of microtubule binding proteins. Microtubule lattice diffusion offers distinct advantages as a transport mechanism including speed, bi-directional microtubule end targeting, and no requirement for direct chemical energy (ie. ATP). It remains to be seen whether a universal binding mechanism for this interaction will be identified but electrostatic interactions appear to play a significant role. In the meantime, the well-studied subject of DNA binding proteins that diffuse along the DNA backbone provides an insightful analogue for understanding the nature of microtubule based diffusional motility.
Previously published online as a Cell Cycle E-publication: http://www.landesbioscience.com/journals/cc/abstract.php?id=3134
KEY WORDSkinesin-13, microtubule, tubulin, MCAK, depolymerization, mitosis, meiosis, dynamic instability
ABBREVIATIONS
MTs
Brief ReportThe Role of the Kinesin-13 Neck in Microtubule Depolymerization
ABSTRACTTo ensure genetic integrity, replicated chromosomes must be accurately distributed to daughter cells-a process that is accomplished on the microtubule spindle. Kinesin-13 motors play an essential role in this process by performing regulated microtubule depolymerization. We set out to dissect the depolymerization mechanism of these kinesins, and in particular, the role of their conserved neck sequence. We used a monomeric kinesin-13 MCAK, consisting of the neck and motor core, which has strong depolymerizing activity. In the presence of a non-hydrolysable ATP analogue, this construct induced formation of rings around microtubules. The rings are built from tubulin protofilaments that are bent by the kinesin-13 motor engaged at the ATP-binding step of its ATPase cycle. Our data suggest that the ring-microtubule interaction is mediated by the neck and support the idea of a role for the kinesin-13 neck in depolymerization efficiency, acting by optimizing release of tubulin from microtubule ends.
The kinesin-13 motor protein family members drive the removal of tubulin from microtubules (MTs) to promote MT turnover. A point mutation of the kinesin-13 family member mitotic centromere-associated kinesin/Kif2C (E491A) isolates the tubulin-removal conformation of the motor, and appears distinct from all previously described kinesin-13 conformations derived from nucleotide analogues. The E491A mutant removes tubulin dimers from stabilized MTs stoichiometrically in adenosine triphosphate (ATP) but is unable to efficiently release from detached tubulin dimers to recycle catalytically. Only in adenosine diphosphate (ADP) can the mutant catalytically remove tubulin dimers from stabilized MTs because the affinity of the mutant for detached tubulin dimers in ADP is low relative to lattice-bound tubulin. Thus, the motor can regenerate for further cycles of disassembly. Using the mutant, we show that release of tubulin by kinesin-13 motors occurs at the transition state for ATP hydrolysis, which illustrates a significant divergence in their coupling to ATP turnover relative to motile kinesins.
Kinetochores are multifunctional supercomplexes that link chromosomes to dynamic microtubule tips. Groups of proteins from the kinetochore are arranged into distinct subcomplexes that co-purify under stringent conditions and cause similar phenotypes when mutated. By co-expressing all the components of a given subcomplex from a polycistronic plasmid in bacteria, many labs have had great success in purifying active subcomplexes. This has enabled the study of how the microtubule binding subcomplexes of the kinetochore interact with both the microtubule lattice and dynamic microtubule tips. Here we outline methods for rapid cloning of polycistronic vectors for expression of kinetochore subcomplexes, their purification, and techniques for functional analysis using Total Internal Reflection Fluorescence Microscopy (TIRFM).
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