Kin I Kinesins: Insights into the Mechanism of Depolymerization

ABSTRACT

Kin I kinesins are members of the diverse kinesin superfamily of molecular motors. Whereas most kinesins use ATP to move along microtubules, Kin I kinesins depolymerize microtubules rather than walk along them. Functionally, this distinct subfamily of kinesins is important in regulating cellular microtubule dynamics and plays a crucial role in spindle assembly and chromosome segregation. The molecular mechanism of Kin I-induced microtubule destabilization is as yet unclear. It is generally believed that Kin Is induce a structural change on the microtubule that leads to microtubule destabilization. Recently, much progress has been made towards understanding how Kin Is may cause this structural change, and how ATPase activity is employed in the catalytic cycle.     

Kin I kinesins: insights into the mechanism of depolymerization

Kin I kinesins are members of the diverse kinesin superfamily of molecular motors. Whereas most kinesins use ATP to move along microtubules, Kin I kinesins depolymerize microtubules rather than walk along them. Functionally, this distinct subfamily of kinesins is important in regulating cellular microtubule dynamics and plays a crucial role in spindle assembly and chromosome segregation. The molecular mechanism of Kin I-induced microtubule destabilization is as yet unclear. It is generally believed that Kin Is induce a structural change on the microtubule that leads to microtubule destabilization. Recently, much progress has been made towards understanding how Kin Is may cause this structural change, and how ATPase activity is employed in the catalytic cycle.     

The Kin I kinesins are microtubule end-stimulated ATPases

The Kin I kinesins are microtubule-destabilizing enzymes important for neuronal transport, spindle assembly, and chromosome segregation. now show that the Kin I MCAK is a microtubule end-stimulated ATPase that can catalytically depolymerize MT's.     

A Kin I-Independent Pacman: Flux Mechanism for Anaphase A

Anaphase A chromatid-to-pole motion is fundamental for proper chromosome segregation in most systems. During the past several decades, two models for the mechanism of anaphase A have come to prominence. The Pacman model posits that chromatids induce the depolymerization of microtubule plus-ends embedded in kinetochores, thereby ‘chewing’ their way poleward. Alternatively, the Poleward-flux model posits that chromatids are ‘reeled-in’ to poles by the continual depolymerization of the minus-ends of kinetochore-associated microtubules, which are focused at spindle poles. In a recent study, we reported that anaphase A in Drosophila requires the depolymerization of both ends of kinetochore-associated microtubules, simultaneously. This is driven by two members of the Kin I subfamily of kinesins, termed KLP59C and KLP10A, which target specifically to chromatids and spindle poles, respectively. We have termed this hybrid of Pacman and Poleward flux the Kin I-dependent Pacman-flux mechanism for anaphase A. Here, we discuss the implications of these findings and explore potential additional components required to drive chromatid-to-pole motion by such a mechanism.     

XMAP215: a key component of the dynamic microtubule cytoskeleton

Microtubules are essential for various cellular processes including cell division and intracellular organization. Their function depends on their ability to rearrange their distribution at different times and places. Microtubules are dynamic polymers and their behaviour is described as dynamic instability. Rearrangement of the microtubule cytoskeleton is made possible by proteins that modulate the parameters of dynamic instability. Studies using Xenopus egg extracts led to identification of a microtubule-associated protein called XMAP215 as a major regulator of physiological microtubule dynamics. XMAP215 belongs to an evolutionarily conserved protein family present in organisms ranging from yeast to mammals. Together with members of the Kin I family of kinesins, XMAP215 and its orthologues form an essential circuit for generating dynamic microtubules in vivo.     

Conventional kinesin mediates microtubule-microtubule interactions in vivo

Conventional kinesin is a ubiquitous organelle transporter that moves cargo toward the plus-ends of microtubules. In addition, several in vitro studies indicated a role of conventional kinesin in cross-bridging and sliding microtubules, but in vivo evidence for such a role is missing. In this study, we show that conventional kinesin mediates microtubule-microtubule interactions in the model fungus Ustilago maydis. Live cell imaging and ultrastructural analysis of various mutants in Kin1 revealed that this kinesin-1 motor is required for efficient microtubule bundling and participates in microtubule bending in vivo. High levels of Kin1 led to increased microtubule bending, whereas a rigor-mutation in the motor head suppressed all microtubule motility and promoted strong microtubule bundling, indicating that kinesin can form cross-bridges between microtubules in living cells. This effect required a conserved region in the C terminus of Kin1, which was shown to bind microtubules in vitro. In addition, a fusion protein of yellow fluorescent protein and the Kin1tail localized to microtubule bundles, further supporting the idea that a conserved microtubule binding activity in the tail of conventional kinesins mediates microtubule-microtubule interactions in vivo.     

Two kinesin-like Kin I family proteins in fission yeast regulate the establishment of metaphase and the onset of anaphase A

BACKGROUND: Metaphase is thought to be a force-equilibrium state of "tug of war," in which poleward forces are pulling kinetochores and counteracting the cohesive forces between the centromeres. Unlike conventional kinesins, members of the Kin I family are microtubule-depolymerizing enzymes, which are expected to be molecules that could generate poleward forces. RESULTS: We have characterized mitotic roles of two Kin I homologs, Klp5 and Klp6, in fission yeast. Klp5 and Klp6 colocalize to the mitotic kinetochores and the spindle midzone. These two proteins form a heterocomplex, but not a homocomplex. Albeit not essential, both proteins are required for accurate chromosome segregation and normal morphology of interphase microtubules. Time-lapse live analysis using GFP-alpha-tubulin indicates that these mutants spend a much longer time (2-fold) in mitosis before the initiation of anaphase B. Further observation using kinetochore and centromere markers shows that, in these mutants, sister centromeres move back and forth between the two poles, indicating that entry into anaphase A is delayed. This is supported by live image analysis showing that Cut2 securin is retained during the prolonged mitosis. Furthermore, the mitotic extension is dependent upon the Mad2 spindle checkpoint. CONCLUSIONS: We discuss two models of Kin I function in fission yeast. One proposes that Klp5 and Klp6 are required for efficient capturing of kinetochores by the spindles, while the other proposes that they are required to generate tension upon kinetochore capturing. Kin I, therefore, plays a fundamental role in the establishment of metaphase, probably by generating poleward forces at the kinetochores.     

Regulation of microtubule dynamics by kinesins

The simple mechanistic and functional division of the kinesin family into either active translocators or non-motile microtubule depolymerases was initially appropriate but is now proving increasingly unhelpful, given evidence that several translocase kinesins can affect microtubule dynamics, whilst non-translocase kinesins can promote microtubule assembly and depolymerisation. Such multi-role kinesins act either directly on microtubule dynamics, by interaction with microtubules and tubulin, or indirectly, through the transport of other factors along the lattice to the microtubule tip. Here I review recent progress on the mechanisms and roles of these translocase kinesins.     

Stu2 promotes mitotic spindle elongation in anaphase

During anaphase, mitotic spindles elongate up to five times their metaphase length. This process, known as anaphase B, is essential for correct segregation of chromosomes. Here, we examine the control of spindle length during anaphase in the budding yeast Saccharomyces cerevisiae. We show that microtubule stabilization during anaphase requires the microtubule-associated protein Stu2. We further show that the activity of Stu2 is opposed by the activity of the kinesin-related protein Kip3. Reexamination of the kinesin homology tree suggests that KIP3 is the S. cerevisiae orthologue of the microtubule-destabilizing subfamily of kinesins (Kin I). We conclude that a balance of activity between evolutionally conserved microtubule-stabilizing and microtubule-destabilizing factors is essential for correct spindle elongation during anaphase B.     

Myosin-V, Kinesin-1, and Kinesin-3 cooperate in hyphal growth of the fungus Ustilago maydis

Long-distance transport is crucial for polar-growing cells, such as neurons and fungal hyphae. Kinesins and myosins participate in this process, but their functional interplay is poorly understood. Here, we investigate the role of kinesin motors in hyphal growth of the plant pathogen Ustilago maydis. Although the microtubule plus-ends are directed to the hyphal tip, of all 10 kinesins analyzed, only conventional kinesin (Kinesin-1) and Unc104/Kif1A-like kinesin (Kinesin-3) were up-regulated in hyphae and they are essential for extended hyphal growth. deltakin1 and deltakin3 mutant hyphae grew irregular and remained short, but they were still able to grow polarized. No additional phenotype was detected in deltakin1rkin3 double mutants, but polarity was lost in deltamyo5rkin1 and deltamyo5rkin3 mutant cells, suggesting that kinesins and class V myosin cooperate in hyphal growth. Consistent with such a role in secretion, fusion proteins of green fluorescent protein and Kinesin-1, Myosin-V, and Kinesin-3 accumulate in the apex of hyphae, a region where secretory vesicles cluster to form the fungal Spitzenk?rper. Quantitative assays revealed a role of Kin3 in secretion of acid phosphatase, whereas Kin1 was not involved. Our data demonstrate that just two kinesins and at least one myosin support hyphal growth.     

The kinesin-related protein MCAK is a microtubule depolymerase that forms an ATP-hydrolyzing complex at microtubule ends

MCAK belongs to the Kin I subfamily of kinesin-related proteins, a unique group of motor proteins that are not motile but instead destabilize microtubules. We show that MCAK is an ATPase that catalytically depolymerizes microtubules by accelerating, 100-fold, the rate of dissociation of tubulin from microtubule ends. MCAK has one high-affinity binding site per protofilament end, which, when occupied, has both the depolymerase and ATPase activities. MCAK targets protofilament ends very rapidly (on-rate 54 micro M(-1).s(-1)), perhaps by diffusion along the microtubule lattice, and, once there, removes approximately 20 tubulin dimers at a rate of 1 s(-1). We propose that up to 14 MCAK dimers assemble at the end of a microtubule to form an ATP-hydrolyzing complex that processively depolymerizes the microtubule.     

New Insights into the Coupling between Microtubule Depolymerization and ATP Hydrolysis by Kinesin-13 Protein Kif2C

Kinesin-13 proteins depolymerize microtubules in an ATP hydrolysis-dependent manner. The coupling between these two activities remains unclear. Here, we first studied the role of the kinesin-13 subfamily-specific loop 2 and of the KVD motif at the tip of this loop. Shortening the loop, the lysine/glutamate interchange and the additional Val to Ser substitution all led to Kif2C mutants with decreased microtubule-stimulated ATPase and impaired depolymerization capability. We rationalized these results based on a structural model of the Kif2C-ATP-tubulin complex derived from the recently determined structures of kinesin-1 bound to tubulin. In this model, upon microtubule binding Kif2C undergoes a conformational change governed in part by the interaction of the KVD motif with the tubulin interdimer interface. Second, we mutated to an alanine the conserved glutamate residue of the switch 2 nucleotide binding motif. This mutation blocks motile kinesins in a post-conformational change state and inhibits ATP hydrolysis. This Kif2C mutant still depolymerized microtubules and yielded complexes of one Kif2C with two tubulin heterodimers. These results demonstrate that the structural change of Kif2C-ATP upon binding to microtubule ends is sufficient for tubulin release, whereas ATP hydrolysis is not required. Overall, our data suggest that the conformation reached by kinesin-13s upon tubulin binding is similar to that of tubulin-bound, ATP-bound, motile kinesins but that this conformation is adapted to microtubule depolymerization.     

Regulation of KinI kinesin ATPase activity by binding to the microtubule lattice

KinI kinesins are important in regulating the complex dynamics of the microtubule cytoskeleton. They are unusual in that they depolymerize, rather than move along microtubules. To determine the attributes of KinIs that distinguish them from translocating kinesins, we examined the ATPase activity, microtubule affinity, and three-dimensional microtubule-bound structure of a minimal KinI motor domain. Together, the kinetic, affinity, and structural data lead to the conclusion that on binding to the microtubule lattice, KinIs release ADP and enter a stable, low-affinity, regulated state, from which they do not readily progress through the ATPase cycle. This state may favor detachment, or diffusion of the KinI to its site of action, the microtubule ends. Unlike conventional translocating kinesins, which are microtubule lattice-stimulated ATPases, it seems that with KinIs, nucleotide-mediated modulation of tubulin affinity is only possible when it is coupled to protofilament deformation. This provides an elegant mechanistic basis for their unique depolymerizing activity.     

Two kinesins transport cargo primarily via the action of one motor: implications for intracellular transport

The number of microtubule motors attached to vesicles, organelles, and other subcellular commodities is widely believed to influence their motile properties. There is also evidence that cells regulate intracellular transport by tuning the number and/or ratio of motor types on cargos. Yet, the number of motors responsible for cargo motion is not easily characterized, and the extent to which motor copy number affects intracellular transport remains controversial. Here, we examined the load-dependent properties of structurally defined motor assemblies composed of two kinesin-1 molecules. We found that a group of kinesins can produce forces and move with velocities beyond the abilities of single kinesin molecules. However, such capabilities are not typically harnessed by the system. Instead, two-kinesin assemblies adopt a range of microtubule-bound configurations while transporting cargos against an applied load. The binding arrangement of motors on their filament dictates how loads are distributed within the two-motor system, which in turn influences motor-microtubule affinities. Most configurations promote microtubule detachment and prevent both kinesins from contributing to force production. These results imply that cargos will tend to be carried by only a fraction of the total number of kinesins that are available for transport at any given time, and provide an alternative explanation for observations that intracellular transport depends weakly on kinesin number in vivo.     

Role of the protein kinase Kin1 and nuclear centering in actomyosin ring formation in fission yeast

Cytokinesis is the last step of the cell cycle, producing two daughter cells inheriting equal genetic information. This process involves the assembly of an actomyosin ring during mitosis. In the fission yeast Schizosaccharomyces pombe, cytokinesis occurs at the geometric cell centre, a position which is defined by the interphase nucleus and the anilin-related Mid1 protein. The pom1Δ, tea1Δ and tea4Δ mutants are defective in restricting Mid1 as a band around the nucleus and misplace the division site. We previously reported that inhibition of the protein kinase Kin1 promoted failure of cytokinesis in pom1Δ and tea1Δ cells but the mechanism involving Kin1 remained elusive. Here we investigated the contribution of Kin1 in cytokinesis. We show that Kin1-GFP has a dynamic cell-cycle regulated distribution. Like pom1Δ and tea1Δ, tea4Δ exhibits a strong genetic interaction with kin1Δ. Using a conditional repressible kin1 allele that only alters interphase nuclear centering, we observed that Kin1 down-regulation severely compromised actomyosin ring formation and septum synthesis in tea4Δ cells. In addition, nuclear displacement induced either by overexpression of a putative catalytically inactive Kin1 mutant, by chemically mediated microtubule depolymerization or by mutation in the par1Δ gene impaired cytokinesis in tea4Δ but not tea4+ cells. We propose that nuclear mispositioning exacerbates the tea4Δ, pom1Δ and tea1Δ cell division phenotype. Our work reveal that nuclear centering becomes essential when Pom1/Tea1/Tea4 function is compromised and that Kin1 expression level is a key regulatory element in this situation. Our results suggest the existence of distinct overlapping control mechanisms to ensure efficient cell division.     

Kinesin-1 plays multiple roles during the vaccinia virus life cycle

The cytoplasmic distribution of cellular structures is known to depend on the balance between plus- and minus-end-directed motor complexes. Among the plus-end-directed kinesins, kinesin-1 and -2 have been implicated in the outward movement of many organelles. To test for a role of kinesin-1 previous studies mostly relied on the overexpression of dominant-negative kinesin-1 constructs. The latter are often cytotoxic, modify the microtubule network and indirect effects related to altered microtubule dynamics should be excluded. In the present study we present a novel kinesin-1 construct, encompassing the first 330 amino acids of kinesin heavy chain fused to GFP (kin330-GFP) that does not alter microtubules upon its overexpression. Kin330-GFP functionally inhibits kinesin-1 because it induces the peri-nuclear accumulation of mitochondria and intermediate filaments. Using this construct and previously established siRNA-mediated knock-down of kinesin-2 function, we assess the role of both motors in the subcellular distribution of distinct steps of the vaccinia virus (VV) life cycle. We show that kinesin-1, but not kinesin-2, contributes to the specific cytoplasmic distribution of three of the four steps of VV morphogenesis tested. These results are discussed with respect to the possible regulation of kinesin-1 during VV infection.     

Functions of the Arabidopsis kinesin superfamily of microtubule-based motor proteins

Plants possess a large number of microtubule-based kinesin motor proteins. While the kinesin-2, 3, 9, and 11 families are absent from land plants, the kinesin-7 and 14 families are greatly expanded. In addition, some kinesins are specifically present only in land plants. The distinctive inventory of plant kinesins suggests that kinesins have evolved to perform specialized functions in plants. Plants assemble unique microtubule arrays during their cell cycle, including the interphase cortical microtubule array, preprophase band, anastral spindle and phragmoplast. In this review, we explore the functions of plant kinesins from a microtubule array viewpoint, focusing mainly on Arabidopsis kinesins. We emphasize the conserved and novel functions of plant kinesins in the organization and function of the different microtubule arrays.     

Catastrophic kinesins: piecing together their mechanism by 3D reconstruction

Kin Is, kinesins with an internal catalytic domain, de-polymerize microtubules from both ends, and the KIF2C crystal structure presented by ([this issue of Cell]) provides provocative evidence to support the theory that the highly conserved sequences are critical structural elements in these catastrophic kinesins.     

Cloning and characterization of Kin5, a novel Tetrahymena ciliary kinesin II

Two Tetrahymena kinesin-like proteins (klps) of the kinesin II subfamily, Kin1 and Kin2, were first identified by Brown et al. [1999: Mol Biol Cell 10: 3081-3096] and shown to be involved in ciliary morphogenesis probably as molecular motors in intraciliary transport (ICT). Using Tetrahymena genomic DNA as a template, we cloned Kin5, another kinesin II subfamily member. Kin5 is upregulated upon deciliation, suggesting that Kin5 is a ciliary protein. Kin5 is most closely related to Osm3, a Caenorhabditis elegans kinesin II; Osm3 and Kin5 have a 56% identity, which rises to 60.4% in the motor domain and a 45% identity in a 60 amino acid region of the C-terminal FERM (4.1, Ezrin, Radixin, Moesin) domain, not present in Kin1 or Kin2, which we hypothesize to be a critical domain either for dimerization or for cargo recognition in ICT. An antibody to a peptide sequence from the tail region of Kin5 localizes in a punctate pattern along the ciliary axoneme, colocalizing with an antibody to the raft protein IFT139. These findings suggest that Kin5 is an ICT motor like Osm3. Osm3 orthologs apparently transport membrane proteins and Kin5 may be the homodimeric kinesin II that performs this function in Tetrahymena cilia.     

Kin17表达促进乳腺上皮细胞MCF-10A增殖

Kin17是一个与DNA复制、DNA修复有关的蛋白质,在人类的各种组织中表达均很低.乳腺上皮细胞生长增殖的分子机制尚未阐明.为了探讨Kin17与乳腺上皮细胞增殖的关系,检测了Kin17在不同增殖状况下的MCF-10A细胞中的表达情况,并把KIN17基因插入真核表达载体pCDNA3.1-(+)中,构建重组质粒pCDNA3.1-Kin17,通过转染MCF-10A细胞,检测Kin17的表达对MCF-10A细胞的增殖、DNA复制活性及信号分子表达的影响;同时在转染Kin17特异性小干扰RNA（siRNA_Kin17）后,分析MCF-10A细胞的Kin17表达及细胞生长状况.实验结果显示,经高浓度血清刺激后,细胞中Kin17表达升高,而且生长越快的细胞,Kin17表达越强;转染重组质粒pCDNA3.1-Kin17明显提高了MCF-10A细胞中Kin17的表达,同时Kin17的上调表达促进了细胞的增殖速度与DNA复制活性,增强了cyclin D1的表达水平.当转染siRNA_Kin17时使Kin17含量下调,MCF-10A细胞生长速度的抑制不显著.实验结果表明,Kin17与乳腺上皮细胞的DNA复制及生长增殖密切相关.对Kin17在乳腺上皮细胞增殖中的作用及分子调控机制的深入探讨,将有助于揭示乳腺癌细胞快速增殖的潜在机制.