Centriole and Golgi microtubule nucleation are dispensable for the migration of human neutrophil-like cells

Neutrophils migrate in response to chemoattractants to mediate host defense. Chemoattractants drive rapid intracellular cytoskeletal rearrangements including the radiation of microtubules from the microtubule-organizing center (MTOC) toward the rear of polarized neutrophils. Microtubules regulate neutrophil polarity and motility, but little is known about the specific role of MTOCs. To characterize the role of MTOCs on neutrophil motility, we depleted centrioles in a well-established neutrophil-like cell line. Surprisingly, both chemical and genetic centriole depletion increased neutrophil speed and chemotactic motility, suggesting an inhibitory role for centrioles during directed migration. We also found that depletion of both centrioles and GM130-mediated Golgi microtubule nucleation did not impair neutrophil directed migration. Taken together, our findings demonstrate an inhibitory role for centrioles and a resilient MTOC system in motile human neutrophil-like cells.     

The effect of the UV microirradiation of the centrosome on cell behavior. III. The ultrastructure of the centrosome after irradiation]

One of the spindle poles of mitotic PK cells was irradiated with UV microbeam in metaphase or in anaphase. Electron microscopy showed that immediately after irradiation the microtubules around the centrosome were maintained, and that the ultrastructure of both irradiated and nonirradiated poles was similar. After microirradiation of the centrosome in metaphase, the mitotic halo around this centrosome was retained, but in due time the number of microtubules was getting less compared to that around the nonirradiated centrosome. When daughter cells with irradiated centrosomes are passing into the interphase, their centrioles are not separated from each other, no primary cilia are formed, and no replication of centrioles occurs. In the interphase cells with irradiated centrosomes, satellites are formed on the active centriole, but centrosome-attached microtubules are practically absent.     

Alteration of the distribution of intermediate filaments in PtK1 cells by acrylamide. II: Effect on the organization of cytoplasmic organelles

The distribution and motility of cytoplasmic particles was examined in PtK1 cells in which intermediate filament networks had been disrupted by acrylamide. In these cells, particles (mitochondria and vesicles) accumulated near the cell center although saltatory movements continued. This left a broad sheet of agranular cytoplasm at the periphery of the cell. Particles were capable of movement into this sheet. Intermediate filaments were absent in the peripheral cytoplasm although microtubules remained in a normal configuration. Particles apparently move along the microtubules. These results indicate that particle movement along microtubules is not dependent upon the normal configuration of intermediate filaments. It is suggested that intermediate filaments are necessary for normal organelle distribution and serve as a matrix with which particles can associate to maintain position.     

The dynamics of reconstitution of microtubules around the cell center after cooling

In interphase PE cells, after cooling (2 h at 0 degree C), some microtubules are retained in the cytoplasm. After the transfer of the cells to a thermostat (37 degrees C), the reconstitution of the microtubule network begins near the cell center. At this time in most of the cells around the center one can see the electron-dense foci of convergence of microtubules which then disappear. The number of microtubules diverging radially from the mother centriole reaches a maximum after 15 to 16 min, that of microtubules growing from the daughter centriole 12 min after the cells are placed at 37 degrees C. 45 min after the heating started the number of radially diverging microtubules somewhat exceeds the control level. These data show that microtubules are associated with the centers only during their growth. The mature microtubule is separated from the center and may be replaced by a new one. Thus, most, of not all, microtubules originate from the cell center, but at any moment only some of the microtubules are associated with it.     

Structure of kinetochore fibres in crane-fly spermatocytes after irradiation with an ultraviolet microbeam: neither microtubules nor actin filaments remain in the irradiated region

We studied chromosome movement after kinetochore microtubules were severed. Severing a kinetochore fibre in living crane-fly spermatocytes with an ultraviolet microbeam creates a kinetochore stub, a birefringent remnant of the spindle fibre connected to the kinetochore and extending only to the edge of the irradiated region. After the irradiation, anaphase chromosomes either move poleward led by their stubs or temporarily stop moving. We examined actin and/or microtubules in irradiated cells by means of confocal fluorescence microscopy or serial-section reconstructions from electron microscopy. For each cell thus examined, chromosome movement had been recorded continuously until the moment of fixation. Kinetochore microtubules were completely severed by the ultraviolet microbeam in cells in which chromosomes continued to move poleward after the irradiation: none were seen in the irradiated regions. Similarly, actin filaments normally present in kinetochore fibres were severed by the ultraviolet microbeam irradiations: the irradiated regions contained no actin filaments and only local spots of non-filamentous actin. There was no difference in irradiated regions when the associated chromosomes continued to move versus when they stopped moving. Thus, one cannot explain motion with severed kinetochore microtubules in terms of either microtubules or actin-filaments bridging the irradiated region. The data seem to negate current models for anaphase chromosome movement and support a model in which poleward chromosome movement results from forces generated within the spindle matrix that propel kinetochore fibres or kinetochore stubs poleward.     

Centrosome reorientation in wound-edge cells is cell type specific

The reorientation of the microtubule organizing center during cell migration into a wound in the monolayer was directly observed in living wound-edge cells expressing gamma-tubulin tagged with green fluorescent protein. Our results demonstrate that in CHO cells, the centrosome reorients to a position in front of the nucleus, toward the wound edge, whereas in PtK cells, the centrosome lags behind the nucleus during migration into the wound. In CHO cells, the average rate of centrosome motion was faster than that of the nucleus; the converse was true in PtK cells. In both cell lines, centrosome motion was stochastic, with periods of rapid motion interspersed with periods of slower motion. Centrosome reorientation in CHO cells required dynamic microtubules and cytoplasmic dynein/dynactin activity and could be prevented by altering cell-to-cell or cell-to-substrate adhesion. Microtubule marking experiments using photoactivation of caged tubulin demonstrate that microtubules are transported in the direction of cell motility in both cell lines but that in PtK cells, microtubules move individually, whereas their movement is more coherent in CHO cells. Our data demonstrate that centrosome reorientation is not required for directed migration and that diverse cells use distinct mechanisms for remodeling the microtubule array during directed migration.     

The Role of Microtubules and Their Dynamics in Cell Migration

Although microtubules have long been implicated in cell locomotion, the mechanism of their involvement remains controversial. Most studies have concluded that microtubules play a positive role by regulating actin polymerization, transporting membrane vesicles to the leading edge, and/or facilitating the turnover of adhesion plaques. Here we used wild-type and mutant CHO cell lines with alterations in tubulin to demonstrate that microtubules can also act to restrain cell motility. Tubulin mutations or low concentrations of drugs that suppress microtubule dynamics without affecting the amount of microtubule polymer inhibited the rate of migration by preventing microtubule reorganization in the trailing portion of the cells where the more dynamic microtubules are normally found. Under these conditions, cells along the edge of a wound still extended lamellipodia and elongated toward the wound but were inhibited in their ability to retract their tails, thus retarding forward progress. The idea that microtubules normally act to restrain cell locomotion was confirmed by treating cells with high concentrations of nocodazole to depolymerize the microtubule network. In the absence of microtubules, wild-type CHO and HeLa cells could still move at near normal speeds, but the movement became more random. We conclude that microtubules act both to restrain cell movement and to establish directionality.     

Comparison of locomotion, chemotaxis and adhesiveness of rabbit neutrophils from blood and peritoneal exudates

We compared the spontaneous behaviour (motility, adhesiveness, locomotion) and the chemotactic responses of exudate and blood-borne neutrophils. Directional locomotion of exudate neutrophils in 2% HSA-Gey's towards exudate fluid was not significantly changed, the response to activated autologous plasma diminished, and that to f-Met-Leu-Phe (10(-9) M) increased in comparison with blood-borne cells. The spontaneous behaviour of exudate cells in 2% HSA-Gey's (no gradient) differed markedly from that of blood-borne cells. In tissue culture medium (2% HSA-Gey's) exudate cells showed heightened motility in suspension and greater adhesiveness to glass substrata. These differences were eliminated by culturing the cells in their physiological media (i.e. plasma or exudate fluid). In contrast to blood-borne cells, exudate neutrophils tended to aggregate spontaneously. There was no correlation between neutrophil aggregation and adhesion to glass substrata of exudate cells in exudate fluid.     

Microtubule organization in lymphoid malignancies.

The abnormal organization of actin-containing microfilaments and vimentin-containing intermediate filaments in neoplastic lymphocytes of T and B cell origin has been described. We investigated microtubules of pathologic cells from 34 lymphoid malignancies, by immunofluorescence microscopy, using monoclonal tubulin antibody. In most cases, apart from two cases of lymphoma, one T cell lymphoma and one B cell lymphoma, interphase leukemia cells, lymphoma cells, and myeloma cells were shown to contain well-organized microtubules which were associated with a microtubule organization center at one end. In the cells of a patient with T cell lymphoma, although microtubules were not visible in the lymphoma cells from lymph nodes, they became visible after 72 hours in culture with concanavalin A (Con A) and interferon alpha. Cap formation was observed with antitubulin monoclonal antibody in the peripheral blood lymphocytes from a chronic lymphocytic leukemia patient, but well-developed microtubules were observed on other occasions in the same patient. There were no obvious structural differences between microtubules in T and B cell lymphoid malignancies, but leukemia cells and lymphoma cells with irregularly shaped nuclei, such as adult T cell leukemia cells and B cell lymphoma cells with cleaved nuclei, had complicated microtubules surrounding their irregular nuclei. In general, after blastogenic stimuli with phytohemagglutinin-P (PHA-P), Con A, and pokeweed mitogen (PWM), the development of the microtubules was proportional to the incorporation of 3H thymidine (3H-TDR). In most cases, after incubation with granulocyte colony-stimulating factor (G-CSF) and interferon alpha, the number of intact cells decreased and the number of degenerated cells increased, but the intact cells had intact microtubules.     

Human leukocytes as viewed by stereo high-voltage electronmicroscopy

Whole-mount preparations of adherent leukocytes were investigated by stereo high-voltage electronmicroscopy (HVEM) to determine the organization of the cytoplast in unstimulated, motile, and phagocytosing cells. A highly ordered structured cytoplast is revealed. All cytoplasmic organelles are held within an intricate network of fine strands, termed the microtrabecular lattice (MTL), which appears more complex in neutrophils than eosinophils or monocytes. In neutrophils, the tendency of the MTL to expand and contract during cell movement and the responding deformability of the granules appear to influence granule shape. This pleomorphism in granule shape is particularly prominent in exceptionally elongated neutrophils that have not established directionality and demonstrate the appearance of having two leading lamellipodia. Results suggest that the morphology of neutrophil granules is influenced by cell motility, and may account for the pleomorphic populations of granules observed by standard transmission EM. Examination of the cytoskeleton of these elongated cells after detergent extraction reveals separation of the centrosome into two solitary centrioles, with each centriole surrounded by an aster of microtubules. A complex network of microfilaments, intermediate filaments, and microtubules is integrated within a thin area of cytoplasm separating the two cell bodies. Interaction between the MTL, microfilaments, intermediate filaments, and microtubules probably influences granule translocation in these elongated cells. Phagocytosis stimulates a reorganization of the cytoplast; all organelles are found in more central areas of the cytoplasm, bordered by a thin area of hyaloplasm. The MTL appears to limit cytoplasmic granules to a compartment around phagocytic vacuoles, which probably provides the framework for efficient phagolysosome fusion.     

Glioblastoma motility occurs in the absence of actin polymer

In fibroblasts and keratocytes, motility is actin dependent, while microtubules play a secondary role, providing directional guidance. We demonstrate here that the motility of glioblastoma cells is exceptional, in that it occurs in cells depleted of assembled actin. Cells display persistent motility in the presence of actin inhibitors at concentrations sufficient to fully disassemble actin. Such actin independent motility is characterized by the extension of cell protrusions containing abundant microtubule polymers. Strikingly, glioblastoma cells exhibit no motility in the presence of microtubule inhibitors, at concentrations that disassemble labile microtubule polymers. In accord with an unconventional mode of motility, glioblastoma cells have some unusual requirements for the Rho GTPases. While Rac1 is required for lamellipodial protrusions in fibroblasts, expression of dominant negative Rac1 does not suppress glioblastoma migration. Other GTPase mutants are largely without unique effect, except dominant positive Rac1-Q61L, and rapidly cycling Rac1-F28L, which substantially suppress glioblastoma motility. We conclude that glioblastoma cells display an unprecedented mode of intrinsic motility that can occur in the absence of actin polymer, and that appears to require polymerized microtubules.     

Dissection of keratin dynamics: different contributions of the actin and microtubule systems

It has only recently been recognized that intermediate filaments (IFs) and their assembly intermediates are highly motile cytoskeletal components with cell-type- and isotype-specific characteristics. To elucidate the cell-type-independent contribution of actin filaments and microtubules to these motile properties, fluorescent epithelial IF keratin polypeptides were introduced into non-epithelial, adrenal cortex-derived SW13 cells. Time-lapse fluorescence microscopy of stably transfected SW13 cell lines synthesizing fluorescent human keratin 8 and 18 chimeras HK8-CFP and HK18-YFP revealed extended filament networks that are entirely composed of transgene products and exhibit the same dynamic features as keratin systems in epithelial cells. Detailed analyses identified two distinct types of keratin motility: (I) Slow (approximately 0.23 microm/min), inward-directed, continuous transport of keratin filament precursor particles from the plasma membrane towards the cell interior, which is most pronounced in lamellipodia. (II) Fast (approximately 17 microm/min), bidirectional and intermittent transport of keratin particles in axonal-type cell processes. Disruption of actin filaments inhibited type I motility while type II motility remained. Conversely, microtubule disruption inhibited transport mode II while mode I continued. Combining the two treatments resulted in a complete block of keratin motility. We therefore conclude that keratin motility relies both on intact actin filaments and microtubules and is not dependent on epithelium-specific cellular factors.     

The interaction of triethyl lead with tubulin and microtubules

The impact of triethyl lead chloride was studied on: (i) the in vitro assembly and disassembly of microtubules from porcine brain by turbidometry and electron microscopy, (ii) the microtubule system of living mammalian cells using immunofluorescence microscopy, (iii) cell motility and chemotaxis employing the methods of phagokinetic track formation and the Boyden chamber assay, respectively, and (iv) thiol groups of the protein tubulin by their titration in the presence and absence of the organic lead compound. Triethyl lead chloride inhibited microtubule assembly and depolymerized preformed microtubules in vitro and in living cells. Random motility of cells was not markedly inhibited by triethyl lead chloride, whereas chemotaxis (directed cellular movement) was strongly inhibited. Triethyl lead chloride was found to interact with 2 thiol groups of the tubulin dimer. The interaction of triethyl lead chloride with the tubulin/microtubule system in vivo likely causes aneuploidy and is at least partly responsible for the cytotoxicity of the drug.     

Regulation of actin-dependent cytoplasmic motility by type II phytochrome occurs within seconds in Vallisneria gigantea epidermal cells

The effects of light on actin-dependent cytoplasmic motility in epidermal cells of green leaves of the aquatic angiosperm Vallisneria gigantea were investigated quantitatively using a custom-made dynamic image analyzer. Cytoplasmic motility was measured by monitoring changes in the brightness of individual pixels on digitized images taken sequentially under infrared light. Acceleration and deceleration of cytoplasmic motility were regulated photoreversibly by type II phytochrome(s). This phytochrome-dependent induction of cytoplasmic motility did not occur uniformly in cytoplasm but took place as scattered patches in which no particular organelles, including nucleus, existed. The induction became detectable at 2.5 s after the start of irradiation with pulsed red light. In cells exposed to microbeam irradiation, cytoplasmic motility was induced only in sites in the cytoplasm that were irradiated directly, whereas nonirradiated neighboring areas were unaffected. The effect was short-lived, disappearing within a few minutes, and no signal was transmitted from an irradiated cell to its neighbors. Anti-phytochrome antibody-responsive protein(s) was detectable in the leaf extract by immunoblot and zinc blot analyses and in cryosections of the epidermis by immunocytochemistry. Although the phytochrome-dependent cytoplasmic motility was blocked by exogenously applied latrunculin B or cytochalasins, treatment of the dark-adapted cells with Ca(2+)-chelating reagents induced the cytoplasmic motility. We have proposed a model for the phytochrome regulation of cytoplasmic motility as one of the earliest responses to a light stimulus.     

Regulation of polarity in cells devoid of actin bundle system after treatment with inhibitors of myosin II activity

Interplay of two cytoskeletal systems--microfilaments and microtubules is essential for directional cell movement. To better understand the role of those cytoskeletal systems in polarization of cells, rat fibroblasts were incubated with drugs inhibiting activity of myosin II: blebbistatin and Y-27632. Both drugs led to disappearance of actin-myosin bundles and mature focal cell-matrix adhesions but did not affect polarization and directional motility. The rate of motility even increased after inhibitor treatment. The characteristic feature of inhibitor-treated fibroblasts was collapse of the cytoplasm accompanied by bundling of microtubules that led to transformation of lamellae into long immobile tails. The only exception was the leading anterior lamella which was not transformed into the tail and supported directional movement of the cell. The tail at the cell rear determined the position of anterior lamella and direction of locomotion. Depolymerization of microtubules by colcemid stopped directional locomotion of inhibitor-treated cells. These data show that integrity of the microtubular system provides the basic mechanism of polarization and orientation which is only modified by interactions with actin-myosin system and cell-substrate adhesions. We suggest that the position of bundled tail microtubules and dispersed microtubules in leading lamella determine polarization in cells lacking stress fibers and focal adhesions. Thus, polarization is based on microtubule-dependent mechanisms both in non-contractile and contractile cells. These mechanisms could switch dependent on circumstances as fibroblasts may acquire non-contractile phenotype, not only after direct inhibition of myosin II but also in certain conditions of microenvironment.     

The chemiluminescence reactions of the blood neutrophils and of peritoneal exudate cells in Syrian hamsters to the intraperitoneal administration of cellular and microbial materials]

The luminol-dependent chemiluminescence (CL) activity of peritoneal exudate cells and blood neutrophils of Syrian hamsters inoculated intraperitoneally with heat-inactivated microbial particles of Candida albicans, (C. albicans), heated irradiated normal cells and native or heated irradiated malignant tumor cells was studied. The inoculation with particles of C. albicans and heated normal cells induced significant activation of CL of peritoneal exudate cells, but did not influence the CL reaction of blood neutrophils. The inoculation of animals with nonheated irradiated tumor cells led to increase of CL response of both peritoneal exudate cells and blood neutrophils. The inoculation with heated irradiated tumor cells did not activate CL of peritoneal exudate cells and led to slight, but long-lasting decrease of CL response of blood neutrophils.     

Effect of drugs affecting microtubular assembly on microtubules, phospholipid synthesis and physiological indices (signalling, growth, motility and phagocytosis) in Tetrahymena pyriformis

Structural changes of microtubules, incorporation of radioactively labelled components into phospholipids, cell motility, growth and phagocytosis were studied under the effect of four drugs affecting microtubular assembly: colchicine, nocodazole, vinblastine and taxol. Although the first three agents influence microtubules in the direction of depolymerization and the fourth stabilizes them, their effects on the structure of microtubules cannot be explained by this. Using confocal microscopy after an acetylated anti-tubulin label, in nocodazole- and colchicine-treated cells, the basal body cages disappear and longitudinal microtubules (LM) became thinner without changing transversal microtubules (TM). After taxol treatment LM also became thinner, however TM disappeared. Under the effect of vinblastine TM became thinner, without influencing LM. These drugs influence the incorporation of components ([(3)H]-serine, [(3)H]-palmitic acid and (32)P) into phospholipids, however their effect is equivocal and cannot be consequently coupled with the effect on the microtubules. Nocodazole, vinblastine and taxol significantly reduced the cell's motility, however colchicine did so to a lesser degree. Vinblastine and nocodazole totally inhibited, and taxol significantly decreased cell growth, while colchicine in a lower concentration increased the multiplication of cells. Phagocytosis was not significantly influenced after 1 min, but after 5 min all the agents studied (except colchicine) significantly inhibited phagocytosis. After 15 and 30 min each molecule caused highly significant inhibition. The experiments demonstrate that drugs affecting microtubular assembly dynamics influence differently the diverse (longitudinal, transversal etc.) microtubular systems of Tetrahymena and also differently influence microtubule-dependent physiological processes. The latter are more dependent on microtubular dynamics than are changes in phospholipid signalling.     

The effect of centrosome UV microbeam irradiation on cell behavior. II. The radiation sequelae in the anaphase: the completion of division and the fate of the interphase cell]

Ultraviolet (280 nm) microbeam irradiation of the centrosome (spindle pole) in the early anaphase slows down and then stops chromosome movement towards the irradiated pole. This happens as a result of rapid (in 1-2 min) disorganization of the half-spindle. Chromosome movement towards the opposite pole continues normally. Irradiation of the centrosome also affects cystotomy--the residual body is formed later than in the normal cell. In some cases additional constrictions are formed or the cytoplasm starts blebbing. Immediately after division the microtubule network in two daughter cells (one of them with irradiated centrosome) is similar. Two hours later in the irradiated cell the amount of microtubules is often less than in the sister cell. Incubation with nocodazole (0.5-1.5 h, 0.15 microgram/ml) shows that in the irradiated cells microtubules radiating from the centrosome are practically absent. Irradiation of other regions of the cytoplasm does not cause any of the effects described above.     

Improvement of stored turkey semen quality as a result of He-Ne laser irradiation

Two experiments were carried out to evaluate the effects of He-Ne laser irradiation at various energy doses on the quality of stored turkey semen. Four semen pools were used in Experiment 1. Each pool was divided into 10 aliquots, nine of which were irradiated with energy doses ranging from 0.144 to 10.8 J/cm2 while the tenth one was not irradiated (control). Each sample was evaluated for motility immediately after irradiation, 24 and 48 h later. Energy doses ranging from 3.24 to 5.4 J/cm2 had higher (P <0.01) sperm motility index (SMI) value compared to the control and samples irradiated with lower and higher laser doses. The energy dose of 3.96 J/cm2 was selected for Experiment 2 to obtain further insight on its effects on turkey sperm preservation for up to 60 h. Each pool of four semen was divided into two aliquots: one represented the control and the other one was irradiated with He-Ne laser at an energy dose of 3.96 J/cm2. Each sample was evaluated for motility and viability immediately after irradiation and then at 12 h intervals up to 60 h. The cell energy charge was also measured by HPLC. Exposure to 3.96 J/cm2 increased the SMI and viability of turkey semen stored for 60 h compared to the control (P <0.05). The cell energy charge of irradiated samples was 200% higher than in the control. Laser irradiation increased the longevity of stored turkey spermatozoa, and might be a useful technique to enhance semen quality in long-term storage.     

The effect of gamma-irradiation on the toxicity of malathion in V79 Chinese hamster cells and Molt-4 human lymphocytes.

There is growing interest in the irradiation of food and agricultural products for insect disinfestation, sprout inhibition, delayed ripening and the reduction of microbiological loads. Extensive research has been done on this process, and irradiation to a maximum dose of 10 kGy is recognized as safe by national and international regulatory agencies. The question has been raised, however, whether irradiation of pesticide residues might produce radiation products that were more toxic or less toxic than the original pesticide. To address this question, we observed the effects of 10 kGy of gamma-radiation on malathion as measured by sister-chromatid exchange (SCE), micronuclei formation, cell survival, growth rate and polyploid formation. We found no significant differences between the effects of irradiated and unirradiated malathion on any of these end-points. Polyploid formation was the most dramatic effect of both irradiated and control malathion on V79 Chinese hamster cells. Cell survival, polyploid formation and growth rate were slightly better in cells treated with irradiated malathion. In Molt-4 human lymphocyte cells, micronuclei formation was not affected by irradiated or unirradiated malathion. Compared to malathion alone, the lack of such biological effects indicates that none of the presumed radiation-induced breakdown products increased or decreased the endpoints studied. The number of SCE was consistently, but not significantly, higher in the cells treated with irradiated malathion. There were no significant differences in cell survival or micronucleus formation in the human lymphocyte cell line Molt-4 treated with irradiated or control malathion. Thus, the irradiation of the pesticide malathion to 10 kGy, a recommended upper dose for most food irradiations, does not significantly alter its toxicity in these in vitro systems.