Development of a differentiated microtubule structure: formation of the chicken erythrocyte marginal band in vivo

The microtubules of mature nucleated erythrocytes are organized into a marginal band that is confined to a single plane at the periphery and that contains essentially the same number of microtubule profiles in each individual cell. Developing erythrocytes can be isolated in homogeneous and synchronously developing populations from chicken embryos. For these reasons, these cells offer a particularly accessible system for study of the pathway leading to a specific microtubule structure in a normal, terminally differentiated animal cell. Along this developmental course, striking changes occur in the properties of the microtubules. Between the postmitotic cell and the formation of the band, a novel arrangement is found: bundles of laterally associated microtubules in each cell, coursing through the cytoplasm but not confined to the periphery. The microtubule organizing centers evident at early stages disappear by the time the band forms. The microtubules in early cells are readily depolymerized by drugs, but that drug sensitivity is lost in the mature cells. The microtubule arrangement of mature cells is faithfully recapitulated after reversible depolymerization, while that of the immature cells is not. Finally, as the band forms, the microtubules and microfilaments increasingly become coaligned. In sum, the microtubules of immature cells have many properties in common with those of cultured cells, but during maturation those properties change. The results suggest that lateral interactions become increasingly important in stabilizing and organizing the microtubules. The properties of marginal band microtubules, and comparable properties of axonal microtubules, may reflect differences between the requirements for cytoskeletal structures of cycling cells and terminally differentiated cells.     

Actin cytoskeleton of resting bovine platelets

Actin filaments in resting discoid bovine platelets were examined by fluorescence and electron microscopy. Rhodamine-phalloidin staining patterns showed a characteristic wheel-like structure which consisted of a central small circle connected by several radial spokes to a large peripheral circle. This wheel-like structure was composed of actin filaments forming a characteristic arrowhead structure with heavy meromyosin from muscle. Actin filaments were densely arrayed in parallel with a marginal microtubule band and radiated out from the center to the periphery. Platelets treated with colchicine lost their marginal microtubule band but retained their wheel-like structure and normal discoid form. Cytochalasin B disrupted the wheel-like structure but not the marginal microtubule band or the normal discoid form. After simultaneous treatment with both cytochalasin B and colchicine, platelets lost their discoid shape. These results suggest that actin filaments and microtubules both play important roles in the maintenance of the discoid shape of resting bovine platelets.     

Isolation of microtubule protein from chicken erythrocytes and determination of the critical concentration for tubulin polymerization in vitro and in vivo

Microtubule protein isolated from nucleated chicken erythrocytes was examined with respect to composition and assembly properties to determine its significance in a microtubule bundle called the marginal band. 1) The protein contains greater than 95% tubulin with small amounts of tau polypeptides and no high molecular weight polypeptides. 2) Microtubule assembly in vitro at 37 degrees C is characterized by low levels of nucleation, despite an abundance of ring oligomers at 5 degrees C, as indicated by long lag times, slow assembly rates, and microtubules that are twice as long as brain microtubules assembled under the same conditions. 3) By radioimmunoassay and sodium dodecyl sulfate gel analysis we determined that 0.6% of erythrocyte protein is tubulin of which three-quarters is in a nonextractable form and is associated with the microtubule bundle and the cell cortex. From these values the in vivo concentrations of total tubulin and tubulin dimer subunits are 2.4 and 0.7 mg/ml, respectively. The value of 0.7 mg/ml is close to the range of values of 0.1-0.6 mg/ml for the critical concentration of erythrocyte microtubule protein in vitro, suggesting that the assembly properties of tubulin in vitro and in vivo are similar.     

Purification and characterization of native conventional kinesin, HSET, and CENP-E from mitotic hela cells

We have developed a strategy for the purification of native microtubule motor proteins from mitotic HeLa cells and describe here the purification and characterization of human conventional kinesin and two human kinesin-related proteins, HSET and CENP-E. We found that the 120-kDa HeLa cell conventional kinesin is an active motor that induces microtubule gliding at approximately 30 microm/min at room temperature. This active form of HeLa cell kinesin does not contain light chains, although light chains were detected in other fractions. HSET, a member of the C-terminal kinesin subfamily, was also purified in native form for the first time, and the protein migrates as a single band at approximately 75 kDa. The purified HSET is an active motor that induces microtubule gliding at a rate of approximately 5 microm/min, and microtubules glide for an average of 3 microm before ceasing movement. Finally, we purified native CENP-E, a kinesin-related protein that has been implicated in chromosome congression during mitosis, and we found that this form of CENP-E does not induce microtubule gliding but is able to bind to microtubules.     

Motor-driven marginal band coiling promotes cell shape change during platelet activation

Platelets float in the blood as discoid particles. Their shape is maintained by microtubules organized in a ring structure, the so-called marginal band (MB), in the periphery of resting platelets. Platelets are activated after vessel injury and undergo a major shape change known as disc to sphere transition. It has been suggested that actomyosin tension induces the contraction of the MB to a smaller ring. In this paper, we show that antagonistic microtubule motors keep the MB in its resting state. During platelet activation, dynein slides microtubules apart, leading to MB extension rather than contraction. The MB then starts to coil, thereby inducing the spherical shape of activating platelets. Newly polymerizing microtubules within the coiled MB will then take a new path to form the smaller microtubule ring, in concerted action with actomyosin tension. These results present a new view of the platelet activation mechanism and reveal principal mechanistic features underlying cellular shape changes.     

Cytoplasmic microtubules in rabbit platelets

Summary A system of microtubules 200–250 Å in diameter is described in the cytoplasm of rabbit platelets. In thin sections they are seen most frequently cut in cross section and at opposite ends of the elliptical platelet where they form a compact bundle containing 10 to 30 microtubules. In other platelet sections they describe a circumferential course 500 to 600 Å deep to the plasma membrane. Occasional microtubules pass between the marginal band and the centre of the platelet.The relationship of the microtubule system to fibres previously observed in the hyaloplasm of platelets spread on films is discussed, and the marginal band of microtubules in platelets equated to that present in nucleated erythrocytes.I am indebted to Dr. E. H. Mercer for his helpful criticisms and to Miss N. Carroll and Mr. R. G. Hill for technical assistance.     

Alterations to the cytoskeleton of erythrocytes infected with frog erythrocytic virus: a fluorescence and electron microscopic study.

Erythrocytes of bullfrogs (Rana catesbeiana) infected with frog erythrocytic virus are spheroid and their nucleus is displaced. In contrast, uninfected cells are ellipsoid and have a centralized nucleus. Fluorescent staining revealed that these changes are correlated with alterations to components of the erythrocyte cytoskeleton. Uninfected erythrocytes contained a broad, continuous marginal band of microtubules, which appeared thinner and interrupted in infected cells. The described disruption of microtubules was associated with an inability to polymerize the tubulin pool with the addition of 12 microM taxol. The arrangement of submembranous microfilaments in uninfected erythrocytes was not significantly altered in infected cells. Vimentin filaments were distributed throughout the cytoplasm and around the nucleus of uninfected cells, and concentrated at the cell and nuclear peripheries. Cytoplasmic pockets that did not contain vimentin filaments were associated with the viral assembly site(s) in infected cells. These data suggest that the distortion of viral-infected erythrocytes could be due, in part, to an irreversible depolymerization of microtubules of the marginal band and a reorganization of the vimentin filament network.     

Isolation of microtubule-associated proteins from carrot cytoskeletons: a 120 kDa map decorates all four microtubule arrays and the nucleus

A method for biochemically isolating microtubule-associated proteins (MAPs) from the detergent-extracted cytoskeletons of carrot suspension cells has been devised. The advantage of cytoskeletons is that filamentous proteins are enriched and separated from vacuolar contents. Depolymerization of cytoskeletal microtubules with calcium at 4°C releases MAPs which are then isolated by association with taxol stabilized neurotubules. Stripped from microtubules (MTs) by salt, then dialysed, the resulting fraction contains a limited number of high molecular weight proteins. Turbidimetric assays demonstrate that this MAP fraction stimulates polymerization of tubulin at concentrations at which it does not self-assemble. By adding it to rhodamine-conjugated tubulin, the fraction can be seen to form radiating arrays of long filaments, unlike MTs induced by taxol. In the electron microscope, these arrays are seen to be composed of mainly single microtubules. Blot-affinity purified antibodies confirm that two of the proteins decorate cellular microtubules and fulfil the criteria for MAPs. Antibodies to an antigenically related triplet of proteins about 60–68 kDa (MAP 65) stain interphase, preprophase band, spindle and phragmoplast microtubules. Antibodies to the 120 kDa MAP also stain all of the MT arrays but labelling of the cortical MTs is more punctate and, unlike anti-MAP 65, the nuclear periphery is also stained. Both the anti-65 kDa and the anti-120 kDa antibodies stain cortical MTs in detergent-extracted, substrate-attached plasma membrane disks ('footprints'). Since the 120 kDa protein is detected at two surfaces (nucleus and plasma membrane) known to support MT growth in plants, it is hypothesized that it may function there in the attachment or nucleation of MTs.     

Erythrocyte microtubule assembly in vitro. Determination of the effects of erythrocyte tau, tubulin isoforms, and tubulin oligomers on erythrocyte tubulin assembly, and comparison with brain microtubule assembly

Two tubulin variants, isolated from chicken brain and erythrocytes and known to have different peptide maps and electrophoretic properties, are demonstrated to exhibit different assembly properties in vitro: 1) erythrocyte tubulin assembles with greater efficiency (lower critical concentration, greater elongation rate) but exhibits a lower nucleation rate than brain tubulin, and 2) erythrocyte tubulin readily forms oligomers whose presence significantly retards the rate of elongation, suggesting that tubulin oligomers may also be important for determining the rate of assembly and the length of microtubules in erythrocytes. Erythrocyte tubulin isolated by cycles of in vitro assembly-disassembly is also demonstrated to contain a 67-kDa tau factor that greatly enhances microtubule nucleation but has little effect on elongation rates or critical concentration. Immunofluorescence microscopy with tau antibody indicates that tau is specifically associated with marginal band microtubules, suggesting that it may be important for determining microtubule function in vivo.     

Structure and composition of the cytoskeleton of nucleated erythrocytes: III. Organization of the cytoskeleton of Bufo marinus erythrocytes as revealed by freeze-dried platinum-carbon replicas and immunofluorescence microscopy

Platinum-carbon (Pt-C) replicas of freeze-dried erythrocyte cytoskeletons of the toad, Bufo marinus, were prepared using a modified Balzers 300 system. Examination in stereo of replicas of the microtubule-containing marginal band revealed filaments projecting from the microtubule walls to form links between adjacent microtubules. These cross-bridging proteins may bundle the microtubules into the configuration of the marginal band (MB) and may also serve to stabilize the structure. The MB appears to have linkages to components of the surface-associated cytoskeleton (SAC). The SAC forms a continuous matrix that spreads across the upper and lower surfaces of the cell adjacent to the plasma membrane and extends around the outer perimeter of the MB. Thus, the SAC encapsulates the MB and the central nucleus. After lysis, the elements of the cytoskeleton remain in a configuration similar to that found in the whole cell. Spectrin (fodrin) and actin were identified by immunofluorescence in the region of the SAC. When labeled with antibodies specific for vimentin and synemin, a network of intermediate filaments can be detected in the region between the nucleus and the MB. These vimentin filaments are also enclosed within the SAC and appear in Pt-C replicas to emerge from the area of the nuclear envelope. As the filaments extend toward the periphery of the cell, they form attachments to the SAC. Attachments of intermediate filaments to both the nucleus and the SAC thus appear to anchor the nucleus in its central position within the cytoskeleton.     

Spatial organization of centrosome-attached and free microtubules in 3T3 fibroblasts

The spatial organization of microtubules is crucial for different cellular processes. It is traditionally supposed that fibroblasts have radial microtubule arrays consisting of long microtubules that run from the centrosome. However, a detailed analysis of the microtubule array in the internal cytoplasm has never been performed. In the current study, we used laser photobleaching to analyze the spatial organization of microtubules in the internal cytoplasm of cultured 3T3 fibroblasts. Cells were injected with Cy-3-labeled tubulin, after which the growth of microtubules in the centrosome region and peripheral parts of cytoplasm was assayed in the bleached zone. In most cases, microtubule growth in the bleached zone occurred rectilinearly; at distances of up to 5 μm, microtubules seldom bend more than 10°–15°. We considered a growing fragment of the microtubule as a vector with the beginning at the point of occurrence and the end at the point where the growth terminated (or the end point after 30 s if microtubule persistent growth proceeded for longer). We defined the direction of microtubule growth in different parts of the cell using these vectors and measured the angle of their deviation from the vector of comparison. In the area of the centrosome, we directed a comparison vector inside the bleached zone from the centrosome to the beginning of the growing microtubule segment; in the lamella and trailing part of the fibroblast, we used the vector of comparison directed along the long axis of the cell from its geometrical center to periphery. The microtubules growing straight away from the centrosome grew along the cell radius. However, at a distance of 10 μm from the centrosome, radially growing microtubules comprised 40% of the overall number, while at a distance of 20 μm, they made up only 25%. The rest of the microtubules grew in different directions, with the preferred angle between their growth direction and cell radius equaling around 90 °. In the lamella and trailing part of the fibroblast, 80% of all microtubules grew along the long axis of the cell or at an angle of no more than 20 °; 10–15% of microtubules grew along axis of the cell but towards the centrosome. Thus, in 3T3 fibroblasts, the radial system of microtubules is perturbed starting at a distance of several microns from the centrosome. In the internal cytoplasm, the microtubule system is completely disordered and, in the stretched parts of the polarized cell (lamella, trailing edge), the microtubule system again becomes well organized; microtubules are preferentially oriented along the long axis of the cell. From the results obtained, we conclude that the orderliness of microtubules at the periphery of the fibroblast is not a consequence of their growth from the centrosome; rather, their orientation is preset by local factors.     

Visualization of detyrosination along single microtubules reveals novel mechanisms of assembly during cytoskeletal duplication in trypanosomes

We have been able to use immunogold labeling with monoclonal antibodies specific for tyrosinated alpha-tubulin to define new microtubule assembly within the T. brucei pellicular cytoskeleton. Using this approach, we have been able to visualize and define the detyrosination gradient along single microtubules in vivo. New microtubules are seen to invade the cytoskeletal array early in the cell cycle between old microtubules. In post-mitotic cells, a unique form of microtubule assembly occurs, with very short microtubules being intercalated in the array. We propose that these are nucleated by lateral interaction with the MAPs on existing adjacent microtubules. This construction pattern suggests a templated morphogenesis of microtubule arrays with semi-conservative distribution to the daughter cells.     

Microtubules' interaction with cell cortex is required for their radial organization, but not for centrosome positioning

Microtubules in interphase mammalian cells usually form a radial array with minus-ends concentrated in the central region and plus-ends placed at the periphery. This is accepted as correct, that two factors determinate the radial organization of microtubules - the centrosome, which nucleate and anchor the microtubules minus-ends, and the interaction of microtubules with cortical dynein, which positions centrosome in the cell center. However, it looks as if there are additional factors, affecting the radial structure of microtubule system. We show here that in aged Vero cytoplasts (17 h after enucleation) microtubule system lost radial organization and became chaotic. To clear up the reasons of that, we studied centrosome activity, its position in the cytoplasts and microtubule dynamics. We found that centrosome in aged cytoplasts was still active and placed in the central region of the cytoplasm, while after total disruption of the microtubules it was displaced from the center. Microtubules in aged cytoplasts were not stabilized, but they lost their ability to stop to grow near cell cortex and continued to grow reaching it. Aged cytoplast lamellae was partially depleted with dynactin though Golgi remained compact indicating dynein activity. We conclude that microtubule stoppage at cell cortex is mediated by some (protein) factors, and these factors influence radial structure of microtubule system. It seems that the key role in centrosome positioning is played by dynein complexes anchored everywhere in the cytoplasm rather than anchored in cell cortex.     

Tubulin, but not microtubules, is the substrate for tubulin:tyrosine ligase in mature avian erythrocytes

Chicken erythrocytes, which contain a marginal band of microtubules, were used to study the influence of the aggregation state of tubulin on the post-translational incorporation of tyrosine into the alpha-tubulin subunit. We found that the incorporation of [14C]tyrosine occurs almost exclusively into the nonassembled tubulin pool. The marginal band was practically not labeled. The low incorporation into microtubules was not due to the lack of tubulin with acceptor capacity since after cold-induced disassembly, an additional amount of [14C]tyrosine could be incorporated. 14C-Tyrosinated tubulin of the nonassembled pool could not be incorporated into microtubules of the marginal band after prolonged incubation at 37 degrees C or when the marginal band was regenerated after cold-induced depolymerization. In erythrocytes, tubulin:tyrosine ligase behaved as a soluble entity when the cells were lysed under microtubule-preserving conditions.     

Centrin-mediated microtubule severing during flagellar excision in Chlamydomonas reinhardtii

Chlamydomonas cells excise their flagella in response to a variety of experimental conditions (e.g., extremes of temperature or pH, alcohol or detergent treatment, and mechanical shear). Here, we show that flagellar excision is an active process whereby microtubules are severed at select sites within the transition zone. The transition zone is located between the flagellar axoneme and the basal body; it is characterized by a pair of central cylinders that have an H shape when viewed in longitudinal section. Both central cylinders are connected to the A tubule of each microtubule doublet of the transition zone by fibers (approximately 5 nm diam). When viewed in cross section, these fibers are seen to form a distinctive stellate pattern characteristic of the transition zone (Manton, I. 1964. J. R. Microsc. Soc. 82:279-285; Ringo. D. L. 1967. J. Cell Biol. 33:543-571). We demonstrate that at the time of flagellar excision these fibers contract and displace the microtubule doublets of the axoneme inward. We believe that the resulting shear force and torsional load act to sever the axonemal microtubules immediately distal to the central cylinder. Structural alterations of the transition zone during flagellar excision occur both in living cells and detergent-extracted cell models, and are dependent on the presence of calcium (greater than or equal to 10(-6) M). Immunolocalization using monoclonal antibodies against the calcium-binding protein centrin demonstrate the presence of centrin in the fiber-based stellate structure of the transition zone of wild-type cells. Examination of the flagellar autotomy mutant, fa-1, which fails to excise its flagella (Lewin, R., and C. Burrascano. 1983. Experientia. 39:1397-1398), demonstrates that the fa-1 lacks the ability to completely contract the fibers of the stellate structure. We conclude that flagellar excision in Chlamydomonas involves microtubule severing that is mediated by the action of calcium-sensitive contractile fibers of the transition zone. These observations have led us to question whether microtubule severing may be a more general phenomenon than previously suspected and to suggest that microtubule severing may contribute to the dynamic behavior of cytoplasmic microtubules in other cells.     

Confocal laser scanning microscopy of microtubule organizational changes in isolated generative cells of Allemanda neriifolia during mitosis

Summary Organizational changes in the microtubules of isolated generative cells of Allemanda neriifolia during mitosis were examined using anti--tubulin and confocal laser scanning microscopy. Due to an improved resolution and a lack of out-of-focus interference, the images of the mitotic cytoskeleton obtained using the confocal microscope are much clearer than those obtained using the non-confocal fluorescence systems. In the confocal microscope one can see clearly that the spindle-shaped interphase cells contain a cage-like cytoskeleton consisting of numerous longitudinally oriented microtubule bundles and some associated smaller bundles. At prophase, the shape of the cells invariably becomes spherical. The microtubule cytoskeleton inside the cells concomitantly changes into a less organized form — consisting of thick bundles, patches, and dots. This structural form is not very stable, and soon afterwards the cytoskeleton changes into a reticulate network. Then the nuclear envelope breaks down, and the microtubules become randomly dispersed throughout the cell. Afterwards, the microtubules reorganize themselves into a number of half-spindle-like structures, each possessing a microtubule-nucleating center. The locations of these centres mark out the positions of the presumptive spindle poles. Numerous microtubules radiate from these centres toward the opposite pole. At metaphase, the microtubules form a number of bipolar spindles. Each spindle has two half-spindles, and each half-spindle has a sharply focused microtubule centre at the pole region. From the centres, kinetochore and non-kinetochore microtubules radiate toward the opposite half-spindle. At anaphase A, sister chromatids separate, the cells elongate, and the kinetochore microtubules disappear; the non-kinetochore microtubules, however, remain, and a new array of microtubules, in the form of a cage, appears. The peripheral cage bundles and the non-kinetochore bundles coverge into a sharp point at the pole region. Later, at anaphase B the microtubule cytoskeleton undergoes reorganization giving rise to a new array of longitudinally oriented microtubule bundles in the cell centre and a cage-like cytoskeleton in the periphery. At telophase, some of the cells elongate further, but some become spherical. The microtubules in the central region of the elongated cell become partially disrupted due to the formation of a phragmoplast-junction-like structure in the mid-interzone region. The microtubule bundles at the periphery are spirally organized, and they appear not to be disrupted by the phragmoplast-like junction. The microtubules in the spherical telophase cells (unlike those seen in the elongated telophase cells) are arranged differently, and no phragmoplast-junction-like structure forms in the spherical cells. The structural and functional significances of some of these new features of the organization of the microtubule cytoskeleton as revealed by the confocal microscope are discussed.     

Asymmetric CLASP-dependent nucleation of noncentrosomal microtubules at the trans-Golgi network

Proper organization of microtubule arrays is essential for intracellular trafficking and cell motility. It is generally assumed that most if not all microtubules in vertebrate somatic cells are formed by the centrosome. Here we demonstrate that a large number of microtubules in untreated human cells originate from the Golgi apparatus in a centrosome-independent manner. Both centrosomal and Golgi-emanating microtubules need gamma-tubulin for nucleation. Additionally, formation of microtubules at the Golgi requires CLASPs, microtubule-binding proteins that selectively coat noncentrosomal microtubule seeds. We show that CLASPs are recruited to the trans-Golgi network (TGN) at the Golgi periphery by the TGN protein GCC185. In sharp contrast to radial centrosomal arrays, microtubules nucleated at the peripheral Golgi compartment are preferentially oriented toward the leading edge in motile cells. We propose that Golgi-emanating microtubules contribute to the asymmetric microtubule networks in polarized cells and support diverse processes including post-Golgi transport to the cell front.     

Dynamic recruitment of Cdc2 to specific microtubule structures during mitosis

A-type cyclin-dependent kinases (CDKs), also known as cdc2, are central to the orderly progression of the cell cycle. We made a functional Green Fluorescent Protein (GFP) fusion with CDK-A (Cdc2-GFP) and followed its subcellular localization during the cell cycle in tobacco cells. During interphase, the Cdc2-GFP fusion protein was found in both the cytoplasm and the nucleus, where it was highly resistant to extraction. In premitotic cells, a bright and narrow equatorial band appeared on the cell surface, resembling the late preprophase band, which disintegrated within 10 min as followed by time-lapse images. Cdc2-GFP was not found on prophase spindles but left the chromatin soon after this stage and associated progressively with the metaphase spindle in a microtubule-dependent manner. Arresting cells in mitosis through the stabilization of microtubules by taxol further enhanced the spindle-localized pool of Cdc2-GFP. Toward the end of mitosis, Cdc2-GFP was found at the midzone of the anaphase spindle and phragmoplast; eventually, it became focused at the midline of these microtubule structures. In detergent-extracted cells, the Cdc2-GFP remained associated with mitotic structures. Retention on spindles was prevented by pretreatment with the CDK-specific inhibitor roscovitine and was enhanced by the protein phosphatase inhibitor okadaic acid. Furthermore, we demonstrate that both the endogenous CDK-A and Cdc2-GFP were cosedimented with taxol-stabilized plant microtubules from cell extracts and that Cdc2 activity was detected together with a fraction of polymerized tubulin. These data provide evidence that the A-type CDKs associate physically with mitotic structures in a microtubule-dependent manner and may be involved in regulating the behavior of specific microtubule arrays throughout mitosis.