The role of +TIPs in directional tip expansion

Aspergillus nidulans is an ideal model to study nuclear migration and intracellular transport by dynein and kinesin owing to its long neuron‐like hyphae, conserved transport mechanisms, and powerful genetics. In this organism, as in other filamentous fungi, microtubules have been implicated in patterning cell shape through polarized tip growth – the hallmark mode of growth that generates the elongated hyphae. Exactly how microtubules regulate tip growth is incompletely understood and remains a fascinating question for various cell types, such as pollen tubes and root hairs. Zeng et al. (2014) describe important new findings in A. nidulans regarding the role of EBA, the master regulator of microtubule plus end‐tracking proteins, in specifying microtubule dynamics required for directional tip growth at the hyphal tip.     

Morphogenetic plastid migration and microtubule organization during megasporogenesis inIsoetes

Summary The large megasporocytes ofIsoetes provide an exceptional system for studying microtubule dynamics in monoplastidic meiosis where plastid polarity assures coordination of plastid and nuclear division by the intimate association of MTOCs with plastids. Division and migration of the plastid in prophase establishes the tetrahedrally arranged cytoplasmic domains of the future spore tetrad and the four plastid-MTOCs serve as focal points of a unique quadripolar microtubule system (QMS). The QMS is a dynamic structure which functions in plastid deployment and contributes directly to development of both first and second division spindles. The nucleation of microtubules at discrete plastid-MTOCs is compared with centrosomal nucleation of microtubules in animal cells where growth of microtubules involves dynamic instability.Abbreviations AMS axial microtubule system - MTOC microtubule organizing center - N nucleus - QMS quadripolar microtubule system - P plastid - PPB preprophase band of microtubules     

Microtubule and katanin-dependent dynamics of microtubule nucleation complexes in the acentrosomal Arabidopsis cortical array

Microtubule nucleation in interphase plant cells primarily occurs through branching from pre-existing microtubules at dispersed sites in the cell cortex. The minus ends of new microtubules are often released from the sites of nucleation, and the free microtubules are then transported to new locations by polymer treadmilling. These nucleation-and-release events are characteristic features of plant arrays in interphase cells, but little is known about the spatiotemporal control of these events by nucleating protein complexes. We visualized the dynamics of two fluorescently-tagged γ-tubulin complex proteins, GCP2 and GCP3, in Arabidopsis thaliana. These probes labelled motile complexes in the cytosol that transiently stabilized at fixed locations in the cell cortex. Recruitment of labelled complexes occurred preferentially along existing cortical microtubules, from which new microtubule was synthesized in a branching manner, or in parallel to the existing microtubule. Complexes localized to microtubules were approximately 10-fold more likely to display nucleation than were complexes recruited to other locations. Nucleating complexes remained stable until daughter microtubules were either completely depolymerized from their plus ends or released by katanin-dependent severing activity. These observations suggest that the nucleation complexes are primarily activated on association with microtubule lattices, and that nucleation complex stability depends on association with daughter microtubules and is regulated in part by katanin activity.     

Cortical control of plant microtubules

The cortical microtubule array of plant cells appears in early G(1) and remodels during the progression of the cell cycle and differentiation, and in response to various stimuli. Recent studies suggest that cortical microtubules are mostly formed on pre-existing microtubules and, after detachment from the initial nucleation sites, actively interact with each other to attain distinct distribution patterns. The plus end of growing microtubules is thought to accumulate protein complexes that regulate both microtubule dynamics and interactions with cortical targets. The ROP family of small GTPases and the mitogen-activated protein kinase pathways have emerged as key players that mediate the cortical control of plant microtubules.     

CLIP-170/tubulin-curved oligomers coassemble at microtubule ends and promote rescues

BACKGROUND: CLIP-170 is a microtubule binding protein specifically located at microtubule plus ends, where it modulates their dynamic properties and their interactions with intracellular organelles. The mechanism by which CLIP-170 is targeted to microtubule ends remains unclear today, as well as its precise effect on microtubule dynamics. RESULTS: We used the N-terminal part of CLIP-170 (named H2), which contains the microtubule binding domains, to investigate how it modulates in vitro microtubule dynamics and structure. We found that H2 primarily promoted rescues (transitions from shrinkage to growth) of microtubules nucleated from pure tubulin and isolated centrosomes, and stimulated microtubule nucleation. Electron cryomicroscopy revealed that H2 induced the formation of tubulin rings in solution and curved oligomers at the extremities of microtubules in assembly conditions. CONCLUSIONS: These results suggest that CLIP-170 targets specifically at microtubule plus ends by copolymerizing with tubulin and modulates microtubule nucleation, polymerization, and rescues by the same basic mechanism with tubulin oligomers as intermediates.     

The centrosome keeps nucleating microtubules but looses the ability to anchor them after the inhibition of dynein-dynactin complex

We inhibited dynein in cells either by the expression of coiled coil-1 (CC1) fragment of dynactin p150Glued subunit or by the microinjection of CC1 protein synthesized in Escherichia coli. CC1 impeded the aggregation of pigment granules in fish melanophores and caused the dispersion of Golgi in Vero and HeLa cells. These data demonstrated the inhibiting effect of CC1 on dynein. In cultured cells, CC1 expression caused the disruption of microtubule array, while the nucleation of new microtubules remained unaltered. This was proved both with in vivo microtubule recovery after nocodazole treatment and with in vitro microtubule polymerization on centrosomes, when the number of nucleated microtubules marginally reduced after the incubation with CC1. Moreover, the inhibiting anti-dynein 74.1 antibodies caused the same effect. Thus we have shown that though dynein is not important for microtubule nucleation, it is essential for the radial organization of microtubules presumably being involved in microtubule anchoring on the centrosome. Published in Russian in Biokhimiya, 2007, Vol. 72, No. 11, pp. 1515–1524.     

Organization and Control of Microtubule Pattern in Centrohelidan Heliozoa*†

SYNOPSIS. Comparative studies of axopodial microtubule pattern in 10 different centrohelidan Heliozoa belonging to the genera Acanthocystis, Raphidiophrys and Heterophrys suggest that 2 basic principles govern pattern formation in centrohelidan Heliozoa. While the larger “open” arrays with unspecified number of microtubules, e.g. in A. aculeata and R. ambigua, may result from self-linkage of additional microtubules around centroplast-nucleated “starter microtubules,” the smaller “closed” arrays with specified microtubule number, e.g. in A. pectinata and H. marina, favor a template-driven linkage mechanism. The centroplast is a highly complex microtubule organizing center involved in the control of orientation, number, and diameter of the axonemes. Its shell may serve as a surface upon which the microtubule nucleating sites assemble, but how the precise positioning of these sites occurs is still open to debate. Some of the unsolved problems of microtubule pattern formation may be explained by the “linker nucleation hypothesis” which is an extension of the “gradion hypothesis” by Roth et al. It is shown how both the formation of closed arrays and the balanced lateral growth of open arrays may result from linker-induced microtubule nucleation.     

A Highlights from MBoC Selection: Fast Microtubule Dynamics in Meiotic Spindles Measured by Single Molecule Imaging: Evidence That the Spindle Environment Does Not Stabilize Microtubules

Metaphase spindles are steady-state ensembles of microtubules that turn over rapidly and slide poleward in some systems. Since the discovery of dynamic instability in the mid-1980s, models for spindle morphogenesis have proposed that microtubules are stabilized by the spindle environment. We used single molecule imaging to measure tubulin turnover in spindles, and nonspindle assemblies, in Xenopus laevis egg extracts. We observed many events where tubulin molecules spend only a few seconds in polymer and thus are difficult to reconcile with standard models of polymerization dynamics. Our data can be quantitatively explained by a simple, phenomenological model—with only one adjustable parameter—in which the growing and shrinking of microtubule ends is approximated as a biased random walk. Microtubule turnover kinetics did not vary with position in the spindle and were the same in spindles and nonspindle ensembles nucleated by Tetrahymena pellicles. These results argue that the high density of microtubules in spindles compared with bulk cytoplasm is caused by local enhancement of nucleation and not by local stabilization. It follows that the key to understanding spindle morphogenesis will be to elucidate how nucleation is spatially controlled.     

Peripheral mechanisms take central stage in microtubule dynamics: Commentary on "Signaling function of α-catenin in microtubule regulation" by Shtutman et al.

Although the centrosome is traditionally viewed as cell’s principle microtubule organizing center (MTOC), regulation of microtubule dynamics at the cell cortex plays an equally important role in the formation of the steady-state microtubule network. Several recent studies, including one published in this issue, reveal that complex signaling mechanisms associated with adherence junctions influence both microtubule nucleation at the centrosome, and the stability of non-centrosomal microtubules.

In the mid 1980s Marc Kirschner and Timothy Mitchison proposed an elegant “search-and-capture” hypothesis that seemed to explain how cells manage to convert a simple radial array of microtubules produced by the centrosome into the complex and precisely regulated asymmetric network found in a typical polarized cell. The key to this mechanism was the selective stabilization of inherently dynamic microtubule plus ends at the certain parts of cell cortex.4 Subsequently, it was shown that microtubule plus ends can in fact be captured and stabilized at diverse cortical loci including focal adhesions and adherence junctions. These observations provided direct support to the search-and-capture hypothesis. However, in recent years it became clear that role of cell cortex in the regulation of microtubule dynamics goes beyond simple stabilization of the plus ends. For example, there is evidence that integrin β1 is involved in the regulation of microtubule nucleation at the centrosome.6 Further, in polarized epithelia, cell cortex serves as the dominant MTOC, effectively replacing the centrosome.5 Thus, cell-cortex mechanisms affect microtubule dynamics both at their plus- and minus ends. The challenge now is to identify molecular pathways underlying this regulation.

A study in this issue of Cell Cycle (Shtutman et al.) suggests that α-catenin, a major component of adherence junctions is responsible for promoting microtubule nucleation and/or stability in a centrosome-independent fashion. Shtutman and coworkers used centrosome-free cytoplasts. The number of microtubules in these cytoplasts is low in the absence of cell-cell contacts but increases to near-normal levels in confluent cultures3 or upon overexpression of cadherins1 suggesting that adherence junctions somehow regulate microtubule dynamics. Shtutman and coworkers now demonstrate a similar increase in microtubule density can be induced by overexpression of a membrane-targeted α catenin. This is an exciting finding because α-catenin is also directly involved in the regulation of actin dynamics2 and thus this molecule emerges as a central player in the global regulation of the cytoskeleton in response to extracellular interactions. Interestingly, expression of non-membrane-targeted α-catenin only mildly increased the density of microtubule network in centrosome-free cytoplasts suggesting that α-catenin needs to be engaged in an activation event at the cell cortex, perhaps within the adherence junction.

Although formation of cell-cell junctions clearly increases the density of microtubule network, microtubule nucleation appears to occur throughout the cytoplasm and not preferentially at adherence junctions in these cells.1 Thus, local interactions at adherence junctions ultimately result in the propagation of a certain factor(s) that influences global microtubule dynamics. The exact nature of this factor or even the general layout of the pathway that alters microtubule dynamics in response to cortical interactions remain unknown. However, the demonstration that α-catenin is one of the molecular players required for this pathway is an important towards the understanding the link between extracellular interactions and microtubule dynamics.

Further Reading

Chausovsky A, Bershadsky AD, Borisy GG. Cadherin-mediated regulation of microtubule dynamics. Nat Cell Biol 2000; 2:797- 804. Gates J, Peifer M. Can 1000 reviews be wrong? Actin, alpha-Catenin, and adherens junctions. Cell 2005; 123:769-72. Karsenti E, Kobayashi S, Mitchison T, Kirschner M. Role of the centrosome in organizing the interphase microtubule array: properties of cytoplasts containing or lacking centrosomes. J Cell Biol 1984; 98:1763-76. Kirschner M, Mitchison T. Beyond self-assembly: from microtubules to morphogenesis. Cell 1986; 45:329-42. Reilein A, Yamada S, Nelson WJ. Self-organization of an acentrosomal microtubule network at the basal cortex of polarized epithelial cells. J Cell Biol 2005; 171:845-55. Reverte CG, Benware A, Jones CW, LaFlamme SE. Perturbing integrin function inhibits microtubule growth from centrosomes, spindle assembly, and cytokinesis. J Cell Biol 2006; 174:491-7.     

Stathmin Regulates Centrosomal Nucleation of Microtubules and Tubulin Dimer/Polymer Partitioning

Stathmin is a microtubule-destabilizing protein ubiquitously expressed in vertebrates and highly expressed in many cancers. In several cell types, stathmin regulates the partitioning of tubulin between unassembled and polymer forms, but the mechanism responsible for partitioning has not been determined. We examined stathmin function in two cell systems: mouse embryonic fibroblasts (MEFs) isolated from embryos +/+, +/−, and −/− for the stathmin gene and porcine kidney epithelial (LLCPK) cells expressing stathmin-cyan fluorescent protein (CFP) or injected with stathmin protein. In MEFs, the relative amount of stathmin corresponded to genotype, where cells heterozygous for stathmin expressed half as much stathmin mRNA and protein as wild-type cells. Reduction or loss of stathmin resulted in increased microtubule polymer but little change to microtubule dynamics at the cell periphery. Increased stathmin level in LLCPK cells, sufficient to reduce microtubule density, but allowing microtubules to remain at the cell periphery, also did not have a major impact on microtubule dynamics. In contrast, stathmin level had a significant effect on microtubule nucleation rate from centrosomes, where lower stathmin levels increased nucleation and higher stathmin levels reduced nucleation. The stathmin-dependent regulation of nucleation is only active in interphase; overexpression of stathmin-CFP did not impact metaphase microtubule nucleation rate in LLCPK cells and the number of astral microtubules was similar in stathmin +/+ and −/− MEFs. These data support a model in which stathmin functions in interphase to control the partitioning of tubulins between dimer and polymer pools by setting the number of microtubules per cell.     

Arabidopsis Cortical Microtubules Are Initiated along,as Well as Branching from,Existing Microtubules

The principles by which cortical microtubules self-organize into a global template hold important implications for cell wall patterning. Microtubules move along bundles of microtubules, and neighboring bundles tend to form mobile domains that flow in a common direction. The bundles themselves move slowly and for longer than the individual microtubules, with domains describing slow rotary patterns. Despite this tendency for colinearity, microtubules have been seen to branch off extant microtubules at ∼45°. To examine this paradoxical behavior, we investigated whether some microtubules may be born on and grow along extant microtubule(s). The plus-end markers Arabidopsis thaliana end binding protein 1a, AtEB1a-GFP, and Arabidopsis SPIRAL1, SPR1-GFP, allowed microtubules of known polarity to be distinguished from underlying microtubules. This showed that the majority of microtubules do branch but in a direction heavily biased toward the plus end of the mother microtubule: few grow backward, consistent with the common polarity of domains. However, we also found that a significant proportion of emergent comets do follow the axes of extant microtubules, both at sites of apparent microtubule nucleation and at cross-over points. These phenomena help explain the persistence of bundles and counterbalance the tendency to branch.     

Structure and microtubule-nucleation activity of isolated Drosophila embryo centrosomes characterized by whole mount scanning and transmission electron microscopy

Experimental approaches in Drosophila melanogaster over the last 20 years have played a fundamental role in elucidating the function, structure and molecular composition of the centrosome. However, quantitative data on the structure and function of the Drosophila centrosome are still lacking. This study uses, for the first time, whole mount electron microscopy in combination with negative staining on isolated centrosomes from the early Drosophila embryos to analyze its dimensions, structure and capacity to nucleate microtubules in vitro. We show that these organelles are on average 0.75 μm in diameter and have abundant pericentriolar material which often appears fibrillar and with bulbous protrusions. Corresponding to the abundant pericentriolar material, extensive microtubule nucleation occurs. Quantification of the number of microtubules nucleated showed that 50–300 active nucleation sites are present. We examined via electron microscopy immunogold labeling the distribution of γ-tubulin, CNN, Asp and the MPM-2 epitopes that are phosphorylated through Polo and the Cdk1 kinase. The distribution of these proteins is homogeneous, with the MPM-2 epitopes exhibiting the highest density. In contrast, centrosomal subdomains are identified using a centriole marker to relate centrosome size to the centriole number by electron microscopy. In conclusion, we present a clear-cut technique assaying and quantifying the microtubule nucleation capacity and antigen distribution complementing molecular studies on centrosome protein complexes, cell organelle assembly and protein composition.     

Kinesin-13 regulates flagellar, interphase, and mitotic microtubule dynamics in Giardia intestinalis

Microtubule depolymerization dynamics in the spindle are regulated by kinesin-13, a nonprocessive kinesin motor protein that depolymerizes microtubules at the plus and minus ends. Here we show that a single kinesin-13 homolog regulates flagellar length dynamics, as well as other interphase and mitotic dynamics in Giardia intestinalis, a widespread parasitic diplomonad protist. Both green fluorescent protein-tagged kinesin-13 and EB1 (a plus-end tracking protein) localize to the plus ends of mitotic and interphase microtubules, including a novel localization to the eight flagellar tips, cytoplasmic anterior axonemes, and the median body. The ectopic expression of a kinesin-13 (S280N) rigor mutant construct caused significant elongation of the eight flagella with significant decreases in the median body volume and resulted in mitotic defects. Notably, drugs that disrupt normal interphase and mitotic microtubule dynamics also affected flagellar length in Giardia. Our study extends recent work on interphase and mitotic kinesin-13 functioning in metazoans to include a role in regulating flagellar length dynamics. We suggest that kinesin-13 universally regulates both mitotic and interphase microtubule dynamics in diverse microbial eukaryotes and propose that axonemal microtubules are subject to the same regulation of microtubule dynamics as other dynamic microtubule arrays. Finally, the present study represents the first use of a dominant-negative strategy to disrupt normal protein function in Giardia and provides important insights into giardial microtubule dynamics with relevance to the development of antigiardial compounds that target critical functions of kinesins in the giardial life cycle.     

The core of the mammalian centriole contains γ-tubulin

Background: The microtubule network, upon which transport occurs in higher cells, is formed by the polymerization of α and β tubulin. The third major tubulin isoform, γ tubulin, is believed to serve a role in organizing this network by nucleating microtubule growth on microtubule-organizing centers, such as the centrosome. Research in vitro has shown that γ tubulin must be restored to stripped centrioles to regenerate the centrosomal functions of duplication and microtubule nucleation.Results We have re-examined the localization of γ tubulin in isolated and in situ mammalian centrosomes using a novel immunocytochemical technique that preserves antigenicity and morphology while allowing increased accessibility. As expected, α tubulin was localized in cytoplasmic and centriolar barrel microtubules and in the associated pericentriolar material. Foci of γ tubulin were observed at the periphery of the organized pericentriolar material, as reported previously, often near the termini of microtubules. A further and major location of γ tubulin was a structure within the proximal end of the centriolar barrel. The distributions were complementary, in that α tubulin was excluded from the core of the centriole, and γ tubulin was excluded from the microtubule barrel.Conclusion We have shown that γ tubulin is localized both in the pericentriolar material and in the core of the mammalian centriole. This result suggests that γ tubulin has a role in the centriolar duplication process, perhaps as a template for growth of the centriolar microtubules, in addition to its established role in the nucleation of astral microtubules.     

γ‐Tubulin Ring Complexes and EB1 play antagonistic roles in microtubule dynamics and spindle positioning

γ‐Tubulin is critical for microtubule (MT) assembly and organization. In metazoa, this protein acts in multiprotein complexes called γ‐Tubulin Ring Complexes (γ‐TuRCs). While the subunits that constitute γ‐Tubulin Small Complexes (γ‐TuSCs), the core of the MT nucleation machinery, are essential, mutation of γ‐TuRC‐specific proteins in Drosophila causes sterility and morphological abnormalities via hitherto unidentified mechanisms. Here, we demonstrate a role of γ‐TuRCs in controlling spindle orientation independent of MT nucleation activity, both in cultured cells and in vivo, and examine a potential function for γ‐TuRCs on astral MTs. γ‐TuRCs locate along the length of astral MTs, and depletion of γ‐TuRC‐specific proteins increases MT dynamics and causes the plus‐end tracking protein EB1 to redistribute along MTs. Moreover, suppression of MT dynamics through drug treatment or EB1 down‐regulation rescues spindle orientation defects induced by γ‐TuRC depletion. Therefore, we propose a role for γ‐TuRCs in regulating spindle positioning by controlling the stability of astral MTs.     

Dissecting the Nanoscale Distributions and Functions of Microtubule-End-Binding Proteins EB1 and ch-TOG in Interphase HeLa Cells

Recently, the EB1 and XMAP215/TOG families of microtubule binding proteins have been demonstrated to bind autonomously to the growing plus ends of microtubules and regulate their behaviour in in vitro systems. However, their functional redundancy or difference in cells remains obscure. Here, we compared the nanoscale distributions of EB1 and ch-TOG along microtubules using high-resolution microscopy techniques, and also their roles in microtubule organisation in interphase HeLa cells. The ch-TOG accumulation sites protruded ∼100 nm from the EB1 comets. Overexpression experiments showed that ch-TOG and EB1 did not interfere with each other’s localisation, confirming that they recognise distinct regions at the ends of microtubules. While both EB1 and ch-TOG showed similar effects on microtubule plus end dynamics and additively increased microtubule dynamicity, only EB1 exhibited microtubule-cell cortex attachment activity. These observations indicate that EB1 and ch-TOG regulate microtubule organisation differently via distinct regions in the plus ends of microtubules.     

The fission yeast transforming acidic coiled coil-related protein Mia1p/Alp7p is required for formation and maintenance of persistent microtubule-organizing centers at the nuclear envelope

Microtubule-organizing centers (MTOCs) concentrate microtubule nucleation, attachment and bundling factors and thus restrict formation of microtubule arrays in spatial and temporal manner. How MTOCs occur remains an exciting question in cell biology. Here, we show that the transforming acidic coiled coil–related protein Mia1p/Alp7p functions in emergence of large MTOCs in interphase fission yeast cells. We found that Mia1p was a microtubule-binding protein that preferentially localized to the minus ends of microtubules and was associated with the sites of microtubule attachment to the nuclear envelope. Cells lacking Mia1p exhibited less microtubule bundles. Microtubules could be nucleated and bundled but were frequently released from the nucleation sites in mia1Δ cells. Mia1p was required for stability of microtubule bundles and persistent use of nucleation sites both in interphase and postanaphase array dynamics. The γ-tubulin–rich material was not organized in large perinuclear or microtubule-associated structures in mia1Δ cells. Interestingly, absence of microtubules in dividing wild-type cells prevented appearance of large γ-tubulin–rich MTOC structures in daughters. When microtubule polymerization was allowed, MTOCs were efficiently assembled de novo. We propose a model where MTOC emergence is a self-organizing process requiring the continuous association of microtubules with nucleation sites.     

Reassembly of microtubules in protoplasts ofSaccharomyces cerevisiae after nocodazole-induced depolymerization

Summary By following microtubule neoformation after their complete destruction by nocodazole, we analyzed the pattern of microtubule nucleation in protoplasts ofSaccharomyces cerevisiae. Using immunofluorescence, the drug was shown to induce rapid and complete disassembly of both cytoplasmic and spindle microtubules and to selectively block protoplast nuclear division at a defined stage of the cell cycle. Treated protoplasts placed in a drug-free environment recovered a more abundant microtubular system. The majority of microtubules re-formed at SPBs whereas a minority of free-ended microtubules nucleated in the cytoplasm of the protoplasts without any detectable association with recognizable nucleation sites. Random nucleation of free microtubules might be induced by high amounts of unpolymerized tubulin likely to be present in the protoplasts at the moment of drug release.Abbreviations MT microtubule - NOCO nocodazole - SPBs spindle pole bodies - PMSF phenylmethylsulfonyl fluoride - BSA bovine serum albumine - sMT spindle microtubule - cMT cytoplasmic microtubule - MTOC microtubule organizing center     

EB1 regulates microtubule dynamics and tubulin sheet closure in vitro

End binding 1 (EB1) is a plus-end-tracking protein (+TIP) that localizes to microtubule plus ends where it modulates their dynamics and interactions with intracellular organelles. Although the regulating activity of EB1 on microtubule dynamics has been studied in cells and purified systems, the molecular mechanisms involved in its specific activity are still unclear. Here, we describe how EB1 regulates the dynamics and structure of microtubules assembled from pure tubulin. We found that EB1 stimulates spontaneous nucleation and growth of microtubules, and promotes both catastrophes (transitions from growth to shrinkage) and rescues (reverse events). Electron cryomicroscopy showed that EB1 induces the initial formation of tubulin sheets, which rapidly close into the common 13-protofilament-microtubule architecture. Our results suggest that EB1 favours the lateral association of free tubulin at microtubule-sheet edges, thereby stimulating nucleation, sheet growth and closure. The reduction of sheet length at microtubule growing-ends together with the elimination of stressed microtubule lattices may account for catastrophes. Conversely, occasional binding of EB1 to the microtubule lattice may induce rescues.     

Stepwise Reconstitution of Interphase Microtubule Dynamics in Permeabilized Cells and Comparison to Dynamic Mechanisms in Intact Cells

Microtubules in permeabilized cells are devoid of dynamic activity and are insensitive to depolymerizing drugs such as nocodazole. Using this model system we have established conditions for stepwise reconstitution of microtubule dynamics in permeabilized interphase cells when supplemented with various cell extracts. When permeabilized cells are supplemented with mammalian cell extracts in the presence of protein phosphatase inhibitors, microtubules become sensitive to nocodazole. Depolymerization induced by nocodazole proceeds from microtubule plus ends, whereas microtubule minus ends remain inactive. Such nocodazole-sensitive microtubules do not exhibit subunit turnover. By contrast, when permeabilized cells are supplemented with Xenopus egg extracts, microtubules actively turn over. This involves continuous creation of free microtubule minus ends through microtubule fragmentation. Newly created minus ends apparently serve as sites of microtubule depolymerization, while net microtubule polymerization occurs at microtubule plus ends. We provide evidence that similar microtubule fragmentation and minus end–directed disassembly occur at the whole-cell level in intact cells. These data suggest that microtubule dynamics resembling dynamics observed in vivo can be reconstituted in permeabilized cells. This model system should provide means for in vitro assays to identify molecules important in regulating microtubule dynamics. Furthermore, our data support recent work suggesting that microtubule treadmilling is an important mechanism of microtubule turnover.