Perinuclear microtubules in postnatal rat heart

Cytoplasmic microtubules can be divided into two subpopulations: 1) those adjacent to the nucleus (perinuclear), and 2) those distributed between the myofilament bundles (nonperinuclear). Previous observations (Cartwright and Goldstein, '83) indicate total cytoplasmic microtubule numeric density increases to a maximum at 5-9 days and decreases to the steady value of the adult muscle. We have examined the numeric density (mean numbers of microtubule profiles per micron2 cross-sectional area) of the perinuclear subpopulation and compared it to the numeric density of the total cytoplasmic microtubule population in postnatally developing rat papillary muscle ages 1, 3, 5, 9, 21, and 42 days, and adult. The perinuclear region was defined as the area around the nucleus which extends to the 0.273 micron from the nuclear envelope. The density of perinuclear microtubules did not change with postnatal development. Our study suggests that perinuclear microtubules are a separate and relatively stable subpopulation of the total population of cytoplasmic microtubules and may serve a function different from that of the more variable nonperinuclear microtubules.     

Nurse cell-oocyte interaction: a new F-actin mesh associated with the microtubule-rich core of an insect ovariole

Fluorescent staining of Rhodnius prolixus ovarioles with rhodaminylphalloidin revealed an elaborate interconnecting meshwork of F-actin encasing the microtubule rich core. The thick actin struts have branches extending partially into the nurse cell lobes extending from the syncytical core. Basally the network ends at the nurse cell-pre-follicular interface and does not extend into the trophic cords. Light microscopy, TEM and SEM show the dense fibrous struts have numerous branch points creating a porous cylindrical collar at the core periphery. The filaments are organized in a dense felt-like anisotropic meshwork rather in parallel arrays. This morphology coupled with the stability of the entire structure in extraction procedures suggests the actin filaments are crosslinked, presumably by associated proteins. Detergent extraction experiments indicate isolation of the mesh is possible. Comparison of Nomarski DIC images with polarizing microscopy images of the same preparations show the F-actin struts are not birefringent while the microtubules of the core are highly birefringent and resistant to nocodazole. Indirect immunocytochemical staining of sections for actin confirmed the F-actin distribution visualized with phalloidin and contrasted markedly with staining pattern for tubulin. The discovery of this prominent actin meshwork must now be incorporated into models attempting to explain the mechanisms underlying polarized nurse cell-oocyte transport.     

Taxol maintains organized microtubule patterns in protoplasts which lead to the resynthesis of organized cell wall microfibrils

Summary We have investigated the effects of microtubule stabilizing conditions upon microtubule patterns in protoplasts and developed a new method for producing protoplasts which have non-random cortical microtubule arrays. Segments of elongating pea epicotyl tissue were treated with the microtubule stabilizing drug taxol for 1 h before enzymatic digestion of the cell walls in the presence of the drug. Anti-tubulin immunofluorescence showed that 40 M taxol preserved regions of ordered microtubules. The microtubules in these regions were arranged in parallel arrays, although the arrays did not always show the transverse orientation seen in the intact tissue. Protoplasts prepared without taxol had microtubules which were random in distribution. Addition of taxol to protoplasts with random microtubule arrangements did not result in organized microtubule arrays. Taxol-treated protoplasts were used to determine whether or not organized microtubule arrays would affect the organization of cell wall microfibrils as new walls were regenerated. We found that protoplasts from taxol-treated tissue which were allowed to regenerate cell walls produced organized arrays of microfibrils whose patterns matched those of the underlying microtubules. Protoplasts from untreated tissue synthesized microfibrils which were disordered. The synthesis of organized microfibrils by protoplasts with ordered microtubules arrays shows that microtubule arrangements in protoplasts influence the arrangement of newly synthesized microfibrils.Abbreviations DIC differential interference contrast - DMSO dimethyl sulfoxide - FITC fluorescein isothiocyanate - IgG immunoglobulin G - PIPES piperazine-N,N-bis[2-ethane-sulfonic acid] - PBS phosphate buffered saline     

Microtubule cortical array organization and plant cell morphogenesis

Plant cell cortical microtubule arrays attain a high degree of order without the benefit of an organizing center such as a centrosome. New assays for molecular behaviors in living cells and gene discovery are yielding insight into the mechanisms by which acentrosomal microtubule arrays are created and organized, and how microtubule organization functions to modify cell form by regulating cellulose deposition. Surprising and potentially important behaviors of cortical microtubules include nucleation from the walls of established microtubules, and treadmilling-driven motility leading to polymer interaction, reorientation, and microtubule bundling. These behaviors suggest activities that can act to increase or decrease the local level of order in the array. The SPIRAL1 (SPR1) and SPR2 microtubule-localized proteins and the radial swollen 6 (rsw-6) locus are examples of new molecules and genes that affect both microtubule array organization and cell growth pattern. Functional tagging of cellulose synthase has now allowed the dynamic relationship between cortical microtubules and the cell-wall-synthesizing machinery to be visualized, providing direct evidence that cortical microtubules can organize cellulose synthase complexes and guide their movement through the plasma membrane as they create the cell wall.     

Analysis of cortical arrays from Tradescantia virginiana at high resolution reveals discrete microtubule subpopulations and demonstrates that confocal images of arrays can be misleading

Cortical microtubule arrays are highly organized networks involved in directing cellulose microfibril deposition within the cell wall. Their organization results from complex interactions between individual microtubules and microtubule-associated proteins. The precise details of these interactions are often not evident using optical microscopy. Using high-resolution scanning electron microscopy, we analyzed extensive regions of cortical arrays and identified two spatially discrete microtubule subpopulations that exhibited different stabilities. Microtubules that lay adjacent to the plasma membrane were often bundled and more stable than the randomly aligned, discordant microtubules that lay deeper in the cytoplasm. Immunolabeling revealed katanin at microtubule ends, on curves, or at sites along microtubules in line with neighboring microtubule ends. End binding 1 protein also localized along microtubules, at microtubule ends or junctions between microtubules, and on the plasma membrane in direct line with microtubule ends. We show fine bands in vivo that traverse and may encircle microtubules. Comparing confocal and electron microscope images of fluorescently tagged arrays, we demonstrate that optical images are misleading, highlighting the fundamental importance of studying cortical microtubule arrays at high resolution.     

S. pombe kinesins-8 promote both nucleation and catastrophe of microtubules

The kinesins-8 were originally thought to be microtubule depolymerases, but are now emerging as more versatile catalysts of microtubule dynamics. We show here that S. pombe Klp5-436 and Klp6-440 are non-processive plus-end-directed motors whose in vitro velocities on S. pombe microtubules at 7 and 23 nm s(-1) are too slow to keep pace with the growing tips of dynamic interphase microtubules in living S. pombe. In vitro, Klp5 and 6 dimers exhibit a hitherto-undescribed combination of strong enhancement of microtubule nucleation with no effect on growth rate or catastrophe frequency. By contrast in vivo, both Klp5 and Klp6 promote microtubule catastrophe at cell ends whilst Klp6 also increases the number of interphase microtubule arrays (IMAs). Our data support a model in which Klp5/6 bind tightly to free tubulin heterodimers, strongly promoting the nucleation of new microtubules, and then continue to land as a tubulin-motor complex on the tips of growing microtubules, with the motors then dissociating after a few seconds residence on the lattice. In vivo, we predict that only at cell ends, when growing microtubule tips become lodged and their growth slows down, will Klp5/6 motor activity succeed in tracking growing microtubule tips. This mechanism would allow Klp5/6 to detect the arrival of microtubule tips at cells ends and to amplify the intrinsic tendency for microtubules to catastrophise in compression at cell ends. Our evidence identifies Klp5 and 6 as spatial regulators of microtubule dynamics that enhance both microtubule nucleation at the cell centre and microtubule catastrophe at the cell ends.     

The effect of low temperature on the microtubules in root meristem cells of spring and winter cultivars of wheat Triticum aestivum L

We have studied the response of the interphase and mitotis microtubule arrays in root meristem cells of spring and winter cultivars of wheat Triticum aestivum L. (Moskovskaya 35 and Moskovskaya 39) during cold stress (1 h at 0 degrees C) and acclimation to cold (3-48 h at 0 degrees C). Our data show that interphase microtubules are more resistant to cold than mitotic arrays in both cultivars. During cold stress the density of endoplasmic microtubules increases in interphase cells of winter plants, yet no changes are detected in cells of spring plants. In mitotic cells of both wheat cultivars the density of microtubules within the kinetochore fibers decreases, yet this effect is more evident in the cells of spring plants. During acclimation to cold of both cultivars, we have observed the disorganization of the interphase cortical arrays and the enhanced growth of endoplasmic microtubule arrays, composed of microtubule converging centers. However, the reaction of mitotic microtubule arrays differs in the cells of winter and spring plants. In winter plants, during prophase diffuse tubulin "halo" accumulates first at perinuclear area, followed by the appearance of the microtubule converging centers. In spring plants, we have observed the formation of the prophase spindle, yet later the prophase spindle is not detected. Metaphase cells of both cultivars show similar aberrations of the mitotic spindle, accumulation of abnormal metaphases and the excessive formation of microtubule converging centers. In telophase cells of both cultivars, acclimation induces similar reaction, resulting in the disorganization of the phragmoplast and the formation of multiple microtubule converging centers. The latter are detected in the perinuclear areas of the daughter cells in winter plants and in the cortical cytoplasm of cells in spring plants. Our data point to the common pathways of microtubule response to cold treatment (0 degrees C). The excessive formation of the microtubule converging centers indicates the activation of microtubule assembly during prolonged cold treatment.     

On the rigidity of the cytoskeleton: are MAPs crosslinkers or spacers of microtubules?

Microtubules are fibers of the cytoskeleton involved in mitosis, intracellular transport, motility and other functions. They contain microtubule-associated proteins (MAPs) bound to their surface which stabilize microtubules and promote their assembly. There has been a debate on additional functions of MAPs, e.g. whether MAPs crosslink microtubules and thus increase their rigidity, or whether they act as spacers between them. We have studied the packing of microtubules in the presence of MAPs by solution X-ray scattering using synchrotron radiation. Microtubules free in solution produce a scattering pattern typical of an isolated hollow cylinder, whereas tightly packed microtubules generate a pattern dominated by interparticle interference. The interference patterns are interpreted in terms of the Hosemann paracrystal concept, adapted for arrays of parallel fibers with hexagonal arrangement in the plane perpendicular to the fiber axes (Briki et al., 1998). Microtubules without MAPs can rapidly and efficiently be compressed by centrifugation, as judged by the transition from a "free microtubule" to a "packed microtubule" X-ray scattering pattern. MAPs make the microtubule array highly resistant to packing, even at high centrifugal forces. This emphasizes the role of MAPs as spacers of microtubules rather than crosslinkers. A possible function is to keep the microtubule tracks free for the approach of motor proteins carrying vesicle or organelle cargoes along microtubules.     

Cytoarchitecture of the ovarioles in scale insects (Hemiptera,Coccinea)

Telotrophic ovarioles of scale insects are subdivided into tropharia (=trophic chambers) and vitellaria that contain single developing oocytes. Tropharium encloses trophocytes (=nurse cells) and arrested oocytes. The central area of the tropharium, termed the trophic core, is devoid of cells. Both trophocytes and oocytes are connected to the trophic core: trophocytes by cytoplasmic processes, oocytes by means of nutritive cords. The trophic core, processes and nutritive cords are filled with bundles of microtubules. The trophocytes contain large lobated nuclei with giant nucleoli. Fluorescent labelling with DAPI has shown that trophocyte nuclei are characterized by high contents of DNA. In the cortical cytoplasm of trophocytes, numerous microfilaments are present. The developing oocyte is surrounded by a simple follicular epithelium. The cortical cytoplasm of follicular cells contains numerous microtubules and microfilaments.     

Control of shape and pattern during the assembly of a large microtubule bundle

Microtubules are packed and linked together in a well defined hexagonal arrangement in the cytopharyngeal microtubule bundles of the ciliate Nassula. Early stages in the morphogenesis of these bundles have been examined. Elements which nucleate assembly of bundle microtubules are apparently closely associated before tubule assembly commences. These nucleating elements seem to be bound together in highly ordered arrays to form microtubule-nucleating-templetes. Each array of elements is attached to the proximal end of a basal body and appears to establish the pattern of tubule packing and cross-sectional shape of a tubule bundle. A self-assembly procedure which accounts for the anisometric growth and shaping of a template and its microtubule bundle is proposed.     

Self-organization of interphase microtubule arrays in fission yeast

Microtubule organization is key to eukaryotic cell structure and function. In most animal cells, interphase microtubules organize around the centrosome, the major microtubule organizing centre (MTOC). Interphase microtubules can also become organized independently of a centrosome, but how acentrosomal microtubules arrays form and whether they are functionally equivalent to centrosomal arrays remains poorly understood. Here, we show that the interphase microtubule arrays of fission yeast cells can persist independently of nuclear-associated MTOCs, including the spindle pole body (SPB)--the centrosomal equivalent. By artificially enucleating cells, we show that arrays can form de novo (self-organize) without nuclear-associated MTOCs, but require the microtubule nucleator mod20-mbo1-mto1 (refs 3-5), the bundling factor ase1 (refs 6,7), and the kinesin klp2 (refs 8,9). Microtubule arrays in enucleated and nucleated cells are morphologically indistinguishable and similarly locate to the cellular axis and centre. By simultaneously tracking nuclear-independent and SPB-associated microtubule arrays within individual nucleated cells, we show that both define the cell centre with comparable precision. We propose that in fission yeast, nuclear-independent, self-organized, acentrosomal microtubule arrays are structurally and functionally equivalent to centrosomal arrays.     

IMMUNOFLUORESCENT LOCALIZATION OF MICROTUBULES THROUGHOUT THE CELL CYCLE IN THE GREEN ALGA MOUGEOTIA (ZYGNEMATACEAE)

Indirect immunofluorescence microscopy was used to survey the three-dimensional distribution of microtubules throughout the cell cycle in the green alga Mougeotia. The network of microtubules present in the cortex of the cells at interphase gradually disappeared before mitosis. A band of cortical microtubules reminiscent of the preprophase band of higher plants surrounded the nuclei of some preprophase cells undergoing cortical microtubule disassembly. Longitudinally oriented bundles of microtubules appeared at the future spindle poles on either side of the nuclei in prophase. These bundles disappeared gradually as the spindle microtubule arrays formed. New spindles had broad poles but these became quite pointed before anaphase. Interzonal microtubules appearing at anaphase persisted until the end of nuclear migration, by which time they were concentrated into narrow bundles on either side of the centripetally forming crosswalls. During decondensation of the chromosomes and early nuclear migration, the spindle poles persisted as sites of microtubule concentration. New arrays of microtubules radiated from these microtubule centers into the cytoplasm ahead of the migrating nuclei. After cytokinesis, reinstatement of cortical microtubules was best observed in regions of the cells remote from the nuclei and associated microtubules. In contrast to higher plants, the first detectable cortical microtubules were short and already oriented transverse to the long axes of the cells.     

Distribution and content of microtubules in relation to the transport of lipid. An ultrastructural quantitative study of the absorptive cell of the small intestine

To determine whether microtubules are linked to intracellular transport in absorptive cells of the proximal intestine, quantitative ultrastructural studies were carried out in which microtubule distribution and content were determined in cells from fasting and fed animals. Rats were given a 1-h meal of standard chow, and tissue was taken from the mid-jejunum before, 1/2 h, and 6 h after the meal. The microtubule content of apical, Golgi, and basal regions of cells was quantitated by point-counting stereology. The results show) that microtubules are localized in intracellular regions of enterocytes (apical and Golgi areas) previously shown to be associated with lipid transport, and that the microtubule content within apical and Golgi regions is significantly (P less than 0.01) reduced during transport of foodstuffs. To determine the effect of inhibition of microtubule assembly on transport, colchicine or vinblastine sulfate was administered to postabsorptive rats, and the lipid and microtubule content of enterocytes determined 1 and 3 h later. After treatment with these agents, lipid was found to accumulate in apical regions of the cells; this event was associated with a significant reduction in microtubule content. In conclusion, the regional distribution of microtubules in enterocytes, the decrease in assembled microtubules after a fat-containing meal, and the accumulation of lipid after the administration of antimicrotubule agents suggest that microtubules are related to lipid transport in enterocytes.     

Confocal Microscopy of Microtubule Cytoskeleton in the Pollen Protoplast of Narcissus

Pollen protoplasts were isolated from the mature pollen grains of Narcissus cyclamineus using cellulase Onozuka'R-10 and pectinase in Bs medium. The microtubule cytoskeleton in the pollen protoplasts was studied using immunofluorescence and confocal microscopy. In the cortical region there was a very complex microtubule network. The network contained numerous whirl-like arrays. The microtubule bundles in the whirl-like arrays were connected with each other by smaller bundles indicating that the arrangement of the whirl-like bundles were quite well organized and not at random. From the cortex to the centre of the protoplast another microtubule network having a structure different from the one in the cortical region was present. This network was much loosely packed than the cortical network. The arrangement of the microtubule bundles near the vegetative nucleus was again different. Numerous granules appeared outside the nuclear membrane. From these granules microtubule bundles radiated towards the cytoplasm. The arrangement of the microtubule network around the generative cell showed no specialized features. But inside the cell three types of microtubule arrays were present. 1. parallel arrays, 2. network, and 3. a mixture of the two. In the bursted pollen protoplast (as a result of osmotic shock treatment )some microtubule bundles could still be found attached to the ghost. The microtubule bundles associated with the ghost were much fragmented. But some still retained their branches and junctions. In the dry cleaved samples,a number of organelles still remained attached to the membrane and they included : microtubules, microfilaments, coated vesicles, endoplasmic reticulum and numerous honey-comb-like apparatus. The honey-comb-like apparatus was named as coated pits by Traas (1984). But we feel that it is more appropriate to call this organelle the honey-comb apparatus and we also believe that this organelle may be involved in microtubule and/or microfilament organization.     

LET-99, GOA-1/GPA-16, and GPR-1/2 are required for aster-positioned cytokinesis

At anaphase, the mitotic spindle positions the cytokinesis furrow [1]. Two populations of spindle microtubules are implicated in cytokinesis: radial microtubule arrays called asters and bundled nonkinetochore microtubules called the spindle midzone [2-4]. In C. elegans embryos, these two populations of microtubules provide two consecutive signals that position the cytokinesis furrow: The first signal is positioned midway between the microtubule asters; the second signal is positioned over the spindle midzone [5]. Evidence for two cytokinesis signals came from the identification of molecules that block midzone-positioned cytokinesis [5-7]. However, no molecules that are only required for, and thus define, the molecular pathway of aster-positioned cytokinesis have been identified. With RNAi screening, we identify LET-99 and the heterotrimeric G proteins GOA-1/GPA-16 and their regulator GPR-1/2 [10-12] in aster-positioned cytokinesis. By using mechanical spindle displacement, we show that the anaphase spindle positions cortical LET-99, at the site of the presumptive cytokinesis furrow. LET-99 enrichment at the furrow depends on the G proteins. GPR-1 is locally reduced at the site of cytokinesis-furrow formation by LET-99, which prevents accumulation of GPR-1 at this site. We conclude that LET-99 and the G proteins define a molecular pathway required for aster-positioned cytokinesis.     

Plasma Membrane-Associated Actin in Bright Yellow 2 Tobacco Cells : Evidence for Interaction with Microtubules

Plasma membrane ghosts form when plant protoplasts attached to a substrate are lysed to leave a small patch of plasma membrane. We have identified several factors, including the use of a mildly acidic actin stabilization buffer and the inclusion of glutaraldehyde in the fixative, that allow immunofluorescent visualization of extensive cortical actin arrays retained on membrane ghosts made from tobacco (Nicotiana tabacum L.) suspension-cultured cells (line Bright Yellow 2). Normal microtubule arrays were also retained using these conditions. Membrane-associated actin is random; it exhibits only limited coalignment with the microtubules, and microtubule depolymerization in whole cells before wall digestion and ghost formation has little effect on actin retention. Actin and microtubules also exhibit different sensitivities to the pH and K⁺ and Ca²⁺ concentrations of the lysis buffer. There is, however, strong evidence for interactions between actin and the microtubules at or near the plasma membrane, because both ghosts and protoplasts prepared from taxol-pretreated cells have microtubules arranged in parallel arrays and an increased amount of actin coaligned with the microtubules. These experiments suggest that the organization of the cortical actin arrays may be dependent on the localization and organization of the microtubules.     

Mutations that encode partially functional beta 2 tubulin subunits have different effects on structurally different microtubule arrays

The testis-specific beta 2 tubulin of Drosophila is required for assembly and function of at least three architecturally different microtubule arrays (Kemphues et al., 1982). Two recessive male-sterile mutations in the B2t locus that encode partially functional, stable, variant forms of beta 2 tubulin cause defects in only certain microtubule-based processes during spermatogenesis. These mutations could thus identify aspects of beta tubulin primary structure critical for function only in specific microtubule arrays. In males carrying the B2t6 mutation, meiotic chromosome segregation and nuclear shaping are normal and flagellar axonemes are formed, but there is a subtle defect in axoneme structure; the outer doublet microtubules fill in with a central core normally seen only in the central pair and accessory microtubules. In homozygous B2t7 males, chromosome movement is usually normal during meiosis but cytokinesis often fails, cytoplasmic microtubules are assembled and nuclear shaping appears to be normal, but the flagellar axoneme lacks structural integrity. In contrast, the B2t8 allele affects a general property of tubulin, the ability to form normal side-to-side association of protofilaments (Fuller et al., 1987), and causes defects in meiosis, axoneme assembly and nuclear shaping. Certain combinations of these beta 2 tubulin mutations show interallelic complementation; in B2t6/B2t8 males functional sperm are produced and both variant subunits are incorporated into mature sperm, in the absence of wild-type beta 2 tubulin. Comparison of the phenotypes of the three partially functional beta 2 tubulin alleles reveals some aspects of tubulin primary structure more important for function in specific subsets of microtubule arrays, and other aspects required for the construction of microtubules in general.     

Encounters between dynamic cortical microtubules promote ordering of the cortical array through angle-dependent modifications of microtubule behavior

Ordered cortical microtubule arrays are essential for normal plant morphogenesis, but how these arrays form is unclear. The dynamics of individual cortical microtubules are stochastic and cannot fully account for the observed order; however, using tobacco (Nicotiana tabacum) cells expressing either the MBD-DsRed (microtubule binding domain of the mammalian MAP4 fused to the Discosoma sp red fluorescent protein) or YFP-TUA6 (yellow fluorescent protein fused to the Arabidopsis alpha-tubulin 6 isoform) microtubule markers, we identified intermicrotubule interactions that modify their stochastic behaviors. The intermicrotubule interactions occur when the growing plus-ends of cortical microtubules encounter previously existing cortical microtubules. Importantly, the outcome of such encounters depends on the angle at which they occur: steep-angle collisions are characterized by approximately sevenfold shorter microtubule contact times compared with shallow-angle encounters, and steep-angle collisions are twice as likely to result in microtubule depolymerization. Hence, steep-angle collisions promote microtubule destabilization, whereas shallow-angle encounters promote both microtubule stabilization and coalignment. Monte Carlo modeling of the behavior of simulated microtubules, according to the observed behavior of transverse and longitudinally oriented cortical microtubules in cells, reveals that these simple rules for intermicrotubule interactions are necessary and sufficient to facilitate the self-organization of dynamic microtubules into a parallel configuration.     

TONNEAU2/FASS regulates the geometry of microtubule nucleation and cortical array organization in interphase Arabidopsis cells

Organization of microtubules into ordered arrays involves spatial and temporal regulation of microtubule nucleation. Here, we show that acentrosomal microtubule nucleation in plant cells involves a previously unknown regulatory step that determines the geometry of microtubule nucleation. Dynamic imaging of interphase cortical microtubules revealed that the ratio of branching to in-bundle microtubule nucleation on cortical microtubules is regulated by the Arabidopsis thaliana B' subunit of protein phosphatase 2A, which is encoded by the TONNEAU2/FASS (TON2) gene. The probability of nucleation from γ-tubulin complexes localized at the cell cortex was not affected by a loss of TON2 function, suggesting a specific role of TON2 in regulating the nucleation geometry. Both loss of TON2 function and ectopic targeting of TON2 to the plasma membrane resulted in defects in cell shape, suggesting the importance of TON2-mediated regulation of the microtubule cytoskeleton in cell morphogenesis. Loss of TON2 function also resulted in an inability for cortical arrays to reorient in response to light stimulus, suggesting an essential role for TON2 and microtubule branching nucleation in reorganization of microtubule arrays. Our data establish TON2 as a regulator of interphase microtubule nucleation and provide experimental evidence for a novel regulatory step in the process of microtubule-dependent nucleation.