Microtubule-organizing centers abnormal in number, structure, and nucleating activity in x-irradiated mammalian cells

Microtubule-organizing centers (MTOCs) in x-irradiated cells were visualized by immunofluorescence using antibody against tubulin. From two to ten reassembly sites of microtubules appeared after microtubule depolymerization at low temperature in an irradiated mitotic cell, in contrast to nonirradiated mitotic cells, which predominantly show 2 MTOCs. A time-course examination of MTOCs in synchronously cultured cells revealed that the multiple MTOCs appeared not immediately after irradiation but at the time of mitosis. Those multiple MTOCs formed at mitosis were inherited by the daughter cells in the next generation. The structure and capacity of the centrosomes to nucleate microtubules in vitro were then examined by electron microscopy of whole-mount preparations as well as by dark-field microscopy. About 70-80% of the centrosomes derived from nonirradiated cells were composed of a pair of centrioles and pericentriolar material, which initiated greater than 100 microtubules. The fraction of fully active complete centrosomes decreased with time of incubation after irradiation. These were replaced by disintegrated centrosomal components such as dissociated centrioles and pericentriolar cloud, a nucleating site with a single centriole, or only an amorphous structure of pericentriolar cloud. Assembly of less than 20 microtubules onto the amorphous cloud without centrioles was seen in 54% of the initiating sites in mitotic cells 2 d after irradiation. These results suggest that x-irradiation causes disintegration of centrosomes at mitosis when the structural and functional reorganization of centrosomes is believed to occur.     

Microtubule-nucleating activity of centrosomes in Chinese hamster ovary cells is independent of the centriole cycle but coupled to the mitotic cycle

The nuclear-centrosome complex was isolated from interphase Chinese hamster ovary (CHO) cells, and, with exogenous brain tubulin as a source of subunits, the centrosome, while attached to the nucleus, was demonstrated to nucleate microtubule formation in vitro. We attempted to quantitate the nucleating activity in order to compare the activity of mitotic and interphase centrosomes. However, the proximity of the nucleus hindered these attempts, and efforts to chemically or mechanically remove the centrosome led to diminished nucleating activity. Therefore, the nuclear-centrosome complex was dissociated biologically through use of the cytochalasin B procedure for enucleation of cells. Cytoplasts were prepared that retained the centrosome. Lysis of the cytoplasts released free centrosomes that could nucleate microtubules in vitro. The nucleating activities of interphase and mitotic centrosomes were compared. In addition, through the use of whole-mount electron microscopy, the configuration of the centrioles was analyzed and the number of microtubules nucleated was determined as a function of the centriole cycle. Nucleating activity did not change discernibly throughout interphase but increased approximately fivefold at the transition to mitosis. Thus, we conclude that the nucleating activity of the centrosome is relatively independent of the centriole cycle but coupled to the mitotic cycle.     

Identification of centrosomal proteins in a human lymphoblastic cell line.

Highly enriched preparations of centrosomes from human T-lymphoblasts KE 37 were analyzed for their protein content. The specific pattern of polypeptides was characterized by an abundant subset of high mol. wt proteins and a major group of proteins with mol. wt ranging from 50 to 65 kd. Several immunoreactive proteins were identified, using a rabbit serum spontaneously reacting with human centrosomes. They include a family of high mol. wt ranging from 180 to 250 kd, a 130-kd protein and a 60-65 kd doublet. These antigens have the following properties: they are localized within the pericentriolar material; their abundance, as judged by centrosome labelling, changes significantly during the cell cycle, the maximum being observed at the pole of the metaphasic spindle; in Taxol-treated cells where the centrosome is no longer acting as a nucleating center, they redistribute at one end of the microtubule arrays in both mitotic and interphasic cells, as expected for nucleating, or capping, proteins. All these properties are compatible with their involvement in microtubule nucleation.     

A novel function of plant histone H1: microtubule nucleation and continuous plus end association

In higher plant cells, various microtubular arrays can be seen despite of their lack of structurally defined microtubule-organizing centers (MTOCs) like centrosomes in animal cells. Little is known about the molecular properties of the microtubule-organizing centers in higher plant cells. The nuclear surface contains one of these microtubule-organizing centers and generates microtubules radially toward the cell periphery (radial microtubules). Previously, we reported that histone H1 possessed the microtubule-organizing activity, and it was suggested that histone H1 localized on the nuclear surfaces in Tobacco BY-2 cells (Nakayama, T., Ishii, T., Hotta, T., and Mizuno, K. J. Biol. Chem. (submitted)). Here we show that histone H1 forms ring-shaped complexes with tubulin, and these complexes nucleated and elongated the radial microtubules continuously (processively) associating with their proximal ends where the incorporation of tubulin occurred. Furthermore, the polarity of radial microtubules was determined to be proximal end plus. Immunofluorescence microscopy of the isolated nuclei revealed that histone H1 localized on the nuclear surfaces, distinct from that in the chromatin. These results indicate that radial microtubules are organized by a novel MTOC that is totally different from MTOCs previously found in either plant or animal cells.     

Interconversion of metaphase and interphase microtubule arrays, as studied by the injection of centrosomes and nuclei into Xenopus eggs

We have designed experiments that distinguish centrosomal , nuclear, and cytoplasmic contributions to the assembly of the mitotic spindle. Mammalian centrosomes acting as microtubule-organizing centers were assayed by injection into Xenopus eggs either in a metaphase or an interphase state. Injection of partially purified centrosomes into interphase eggs induced the formation of extensive asters. Although centrosomes injected into unactivated eggs (metaphase) did not form asters, inhibition of centrosomes is not irreversible in metaphase cytoplasm: subsequent activation caused aster formation. When cytoskeletons containing nuclei and centrosomes were injected into the metaphase cytoplasm, they produced spindle-like structures with clearly defined poles. Electron microscopy revealed centrioles with nucleated microtubules. However, injection of nuclei prepared from karyoplasts that were devoid of centrosomes produced anastral microtubule arrays around condensing chromatin. Co-injection of karyoplast nuclei with centrosomes reconstituted the formation of spindle-like structures with well-defined poles. We conclude from these experiments that in mitosis, the centrosome acts as a microtubule-organizing center only in the proximity of the nucleus or chromatin, whereas in interphase it functions independently. The general implications of these results for the interconversion of metaphase and interphase microtubule arrays in all cells are discussed.     

Regulation of the microtubule nucleating activity of centrosomes in Xenopus egg extracts: role of cyclin A-associated protein kinase

Isolated centrosomes nucleate microtubules when incubated in pure tubulin solutions well below the critical concentration for spontaneous polymer assembly (approximately 15 microM instead of 60 microM). Treatment with urea (2-3 M) does not severely damage the centriole cylinders but inactivates their ability to nucleate microtubules even at high tubulin concentrations. Here we show that centrosomes inactivated by urea are functionally complemented in frog egg extracts. Centrosomes can then be reisolated on sucrose gradients and assayed in different concentrations of pure tubulin to quantify their nucleating activity. We show that the material that complements centrosomes is stored in a soluble form in the egg. Each frog egg contains enough material to complement greater than 6,000 urea-inactivated centrosomes. The material is heat inactivated above 56 degrees C. One can use this in vitro system to study how the microtubule nucleating activity of centrosomes is regulated. Native centrosomes require approximately 15 microM tubulin to begin nucleating microtubules, whereas centrosomes complemented in interphase extracts begin nucleating microtubules around 7-8 microM tubulin. Therefore, the critical tubulin concentrations for polymer assembly off native centrosomes is higher than that observed for the centrosomes first denatured and then complemented in egg extracts. In vivo, the microtubule nucleating activity of centrosomes seems to be regulated by phosphorylation at the onset of mitosis (Centonze, V. E., and G. G. Borisy. 1990. J. Cell Sci. 95:405-411). Since cyclins are major regulators of mitosis, we tested the effect of adding bacterially produced cyclins to interphase egg extracts. Both cyclin A and B activate an H1 kinase in the extracts. Cyclin A-associated kinase causes an increase in the microtubule nucleating activity of centrosomes complemented in the extract but cyclin B does not. The critical tubulin concentration for polymer assembly off centrosomes complemented in cyclin A-treated extracts is similar to that observed for centrosomes complemented in interphase extracts. However, centrosomes complemented in cyclin A treated extracts nucleate much more microtubules at high tubulin concentration. We define this as the "capacity" of centrosomes to nucleate microtubules. It seems that the microtubule nucleating activity of centrosomes can be defined by two distinct parameters: (a) the critical tubulin concentration at which they begin to nucleate microtubules and (b) their capacity to nucleate microtubules at high tubulin concentrations, the latter being modulated by phosphorylation.     

Ordering microtubules

How do cells order their cytoplasm? While microtubule organizing centers have long been considered essential to conferring order by virtue of their microtubule nucleating activity, attention has currently refocused on the role that microtubule motors play in organizing microtubules. An intriguing set of recent findings⁽¹⁾ reveals that cell fragments, lacking microtubule organizing centers, rapidly organize microtubules into a radial array during organelle transport driven by the microtubule motor, cytoplasmic dynein. Further, interaction of radial microtubules with the cell surface centers the array, revealing that centering information resides not with centrosomes but with organized microtubules.     

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.     

Abnormal centrosomes in cold-treated Drosophila embryos

In this study we examine the effect on the centrosomes of cold treatment of early Drosophila embryos. Prolonged cold treatment during the mitotic divisions which lead to the formation of the blastoderm causes arrest at metaphase of the nuclear divisions. When examined with immunofluorescence microscopy the mitotic spindles show marked pole splitting with the formation of supernumerary and irregularly sized centers, all able to nucleate microtubules. In embryos recovered for longer periods the additional organizing centers become ring-shaped and lose their nucleating properties. Cold treatment of embryos during the cellularization of the blastoderm results in marked fragmentation of the centrosomes, but nucleating capacity is preserved. Sometimes the centrioles come away from the pericentriolar material and their structure is seen to be modified.     

A multicomponent assembly pathway contributes to the formation of acentrosomal microtubule arrays in interphase Drosophila cells

In animal cells, centrosomes nucleate microtubules that form polarized arrays to organize the cytoplasm. Drosophila presents an interesting paradox however, as centrosome-deficient mutant animals develop into viable adults. To understand this discrepancy, we analyzed behaviors of centrosomes and microtubules in Drosophila cells, in culture and in vivo, using a combination of live-cell imaging, electron microscopy, and RNAi. The canonical model of the cycle of centrosome function in animal cells states that centrosomes act as microtubule-organizing centers throughout the cell cycle. Unexpectedly, we found that many Drosophila cell-types display an altered cycle, in which functional centrosomes are only present during cell division. On mitotic exit, centrosomes disassemble producing interphase cells containing centrioles that lack microtubule-nucleating activity. Furthermore, steady-state interphase microtubule levels are not changed by codepleting both gamma-tubulins. However, gamma-tubulin RNAi delays microtubule regrowth after depolymerization, suggesting that it may function partially redundantly with another pathway. Therefore, we examined additional microtubule nucleating factors and found that Mini-spindles, CLIP-190, EB1, or dynein RNAi also delayed microtubule regrowth; surprisingly, this was not further prolonged when we codepleted gamma-tubulins. Taken together, these results modify our view of the cycle of centrosome function and reveal a multi-component acentrosomal microtubule assembly pathway to establish interphase microtubule arrays in Drosophila.     

Isolated Plant Nuclei Nucleate Microtubule Assembly: The Nuclear Surface in Higher Plants Has Centrosome-like Activity

In most eukaryotic cells, microtubules (MTs) are assembled at identified nucleating sites, such as centrosomes or spindle pole bodies. Higher plant cells do not possess such centrosome-like structures. Thus, the fundamental issues of where and how the intracellular plant MTs are nucleated remain highly debatable. A large body of evidence indicates that plant MTs emerge from the nuclear periphery. In this study, we developed an in vitro assay in which isolated maize nuclei nucleate MT assembly at a tubulin concentration (14 [mu]M of neurotubulin) that is not efficient for spontaneous MT assembly. No MT-stabilizing agents, such as taxol or dimethyl sulfoxide, were used. Our model provides evidence that the nuclear surface functions as a MT-nucleating site in higher plant cells. A monoclonal antibody raised against a pericentriolar antigen immunostained the surface of isolated nuclei, and a 100-kD polypeptide in 4 M urea-treated nuclear extracts was detected.     

Abnormal centrosomes in cold-treated Drosophila embryos

In this study we examine the effect on the centrosomes of cold treatment of early Drosophila embryos. Prolonged cold treatment during the mitotic divisions which lead to the formation of the blastoderm causes arrest at metaphase of the nuclear divisions. When examined with immunofluorescence microscopy the mitotic spindles show marked pole splitting with the formation of supernumerary and irregularly sized centers, all able to nucleate microtubules. In embryos recovered for longer periods the additional organizing centers become ring-shaped and lose their nucleating properties. Cold treatment of embryos during the cellularization of the blastoderm results in marked fragmentation of the centrosomes, but nucleating capacity is preserved. Sometimes the centrioles come away from the pericentriolar material and their structure is seen to be modified.     

Ran,a GTP-binding protein involved in nucleocytoplasmic transport and microtubule nucleation,relocates from the manchette to the centrosome region during rat spermiogenesis

Ran, a Ras-related GTPase, is required for transporting proteins in and out of the nucleus during interphase and for regulating the assembly of microtubules. cDNA cloning shows that rat testis, like mouse testis, expresses both somatic and testis-specific forms of Ran-GTPase. The presence of a homologous testis-specific form of Ran-GTPase in rodents implies that the Ran-GTPase pathway plays a significant role during sperm development. This suggestions is supported by distinct Ran-GTPase immunolocalization sites identified in developing spermatids. Confocal microscopy demonstrates that Ran-GTPase localizes in the nucleus of round spermatids and along the microtubules of the manchette in elongating spermatids. When the manchette disassembles, Ran-GTPase immunoreactivity is visualized in the centrosome region of maturing spermatids. The circumstantial observation that fractionated manchettes, containing copurified centrin-immunoreactive centrosomes, can organize a three-dimensional lattice in the presence of taxol and GTP, points to the role of Ran-GTPase and associated factors in microtubule nucleation as well as the potential nucleating function of spermatid centrosomes undergoing a reduction process. Electron microscopy demonstrates the presence in manchette preparations of spermatid centrosomes, recognized as such by their association with remnants of the implantation fossa, a dense plate observed only at the basal surface of developing spermatid and sperm nuclei. In addition, we have found importin beta1 immunoreactivity in the nucleus of elongating spermatids, a finding that, together with the presence of Ran-GTPase in the nucleus of round spermatids and the manchette, suggest a potential role of Ran-GTPase machinery in nucleocytoplasmic transport. Our expression and localization analysis, correlated with functional observations in other cell systems, suggest that Ran-GTPase may be involved in both nucleocytoplasmic transport and microtubules assembly, two critical events during the development of functional sperm. In addition, the manchette-to-centrosome Ran-GTPase relocation, together with the similar redistribution of various proteins associated to the manchette, suggest the existence of an intramanchette molecular transport mechanism, which may share molecular analogies with intraflagellar transport.     

Direct patterning of centrosome arrays as templates for the assembly of microtubules

We have achieved, for the first time, the selective patterning of centrosomes onto solid substrates. The use of such patterned centrosome arrays as templates for the directed polymerization of microtubules was also demonstrated. Centrosomes are small organelles in animal cells that serve as nucleation and organization centers of microtubules. Directed assembly of microtubules on the patterned centrosome arrays provides a new route to control the positions and directions of microtubules on surfaces. Combining the patterning of the isolated centrosomes and the directed growth of microtubules may lead to the generation of desired microtubule networks for bio-based nanodevices.     

IMMUNOFLUORESCENCE MICROSCOPY OF FERTILIZATION AND PARTHENOGENESIS IN LAMINARIA ANGUSTATA (PHAEOPHYTA)1

Normal fertilization and parthenogenesis of unfertilized eggs were observed in Laminaria angustata Kjellman by indirect immunofluorescence microscopy using a tubulin antibody. Sperm aster formation did not occur at plasmogamy. The centrosome of the egg gradually disappeared. Shortly after karyogamy, one centrosome reappeared near the zygote nucleus. During mitosis, the centrosome replicated and the daughter centrosomes migrated to opposite poles. The mitotic spindle was formed by microtubules that elongated from both poles. After the first cell division, each of the daughter cells received one centrosome that persisted throughout the development of the sporophyte. During parthenogenetic development, abnormal mono-, tri-, and multi-polar spindles were formed. These abnormal spindles caused abnormal nuclear and cytoplasmic division. Thus, cells were produced with 1) no nuclei, 2) multiple nuclei, 3) irregular numbers of chromosomes, and/or 4) no centrosomes. This is one of the reasons for the abortion and abnormal morphogenesis during parthenogenesis. Ultrastructural observations showed that, although cells of some parthogenetic sporophytes have centrioles, cells of almost all abnormally shaped parthenogenetic sporophytes lack centrioles. These results suggest that centrioles are required for normal centrosomal functions in Laminaria. Although centrioles are inherited paternally, some centrosomal material appears to be present or produced de novo in unfertilized eggs.     

Microtubule nucleating sites in higher plant cells identified by an auto-antibody against pericentriolar material

Human scleroderma serum 5051, which is known to recognize the amorphous pericentriolar microtubule organizing center material of a variety of vertebrate cells, was found to immunostain spindle poles of meristematic higher plants from pre-prophase to late anaphase. Subsequently, during cytokinesis, staining was redistributed around the reforming telophase nuclei, but was not evident in the cytokinetic phragmoplast. At the transition between telophase and interphase, before the typical cortical interphase microtubule array was established, short microtubules radiated from the nucleus and in such cells the material recognized by 5051 was located around the daughter nuclei and not the cortex. These observations have led us to propose that the perinuclear region, or the nuclear surface, may function as a nucleation center for both spindle and interphase microtubules in higher plant cells.     

A model for cleavage plane determination in early amphibian and fish embryos

Current models for cleavage plane determination propose that metaphase spindles are positioned and oriented by interactions of their astral microtubules with the cellular cortex, followed by cleavage in the plane of the metaphase plate [1, 2]. We show that in early frog and fish embryos, where cells are unusually large, astral microtubules in metaphase are too short to position and orient the spindle. Rather, the preceding interphase aster centers and orients a pair of centrosomes prior to nuclear envelope breakdown, and the spindle assembles between these prepositioned centrosomes. Interphase asters center and orient centrosomes with dynein-mediated pulling forces. These forces act before astral microtubules contact the cortex; thus, dynein must pull from sites in the cytoplasm, not the cell cortex as is usually proposed for smaller cells. Aster shape is determined by interactions of the expanding periphery with the cell cortex or with an interaction zone that forms between sister-asters in telophase. We propose a model to explain cleavage plane geometry in which the length of astral microtubules is limited by interaction with these boundaries, causing length asymmetries. Dynein anchored in the cytoplasm then generates length-dependent pulling forces, which move and orient centrosomes.     

Making microtubules and mitotic spindles in cells without functional centrosomes

Centrosomes are considered to be the major sites of microtubule nucleation in mitotic cells (reviewed in ), yet mitotic spindles can still form after laser ablation or disruption of centrosome function . Although kinetochores have been shown to nucleate microtubules, mechanisms for acentrosomal spindle formation remain unclear. Here, we performed live-cell microscopy of GFP-tubulin to examine spindle formation in Drosophila S2 cells after RNAi depletion of either gamma-tubulin, a microtubule nucleating protein, or centrosomin, a protein that recruits gamma-tubulin to the centrosome. In these RNAi-treated cells, we show that poorly focused bipolar spindles form through the self-organization of microtubules nucleated from chromosomes (a process involving gamma-tubulin), as well as from other potential sites, and through the incorporation of microtubules from the preceding interphase network. By tracking EB1-GFP (a microtubule-plus-end binding protein) in acentrosomal spindles, we also demonstrate that the spindle itself represents a source of new microtubule formation, as suggested by observations of numerous microtubule plus ends growing from acentrosomal poles toward the metaphase plate. We propose that the bipolar spindle propagates its own architecture by stimulating microtubule growth, thereby augmenting the well-described microtubule nucleation pathways that take place at centrosomes and chromosomes.     

Reconstitution and characterization of budding yeast gamma-tubulin complex

Nucleation of microtubules is central to assembly of the mitotic spindle, which is required for each cell division. gamma-Tubulin is a universal component essential for microtubule nucleation from centrosomes. To elucidate the mechanism of microtubule nucleation in budding yeast we reconstituted and characterized the yeast gamma-tubulin complex (Tub4p complex) produced in insect cells. The recombinant complex has the same sedimentation coefficient (11.6 S) as the native complex in yeast cell extracts and contains one molecule of Spc97p, one molecule of Spc98p, and two molecules of Tub4p. The reconstituted Tub4p complex binds preformed microtubules and has a low nucleating activity, allowing us to begin a detailed analysis of conditions that enhance this nucleating activity. We tested whether binding of the recombinant Tub4p complex to the spindle pole body docking protein Spc110p affects its nucleating activity. The solubility of recombinant Spc110p in insect cells is improved by coexpression with yeast calmodulin (Cmd1p). The Spc110p/Cmd1p complex has a small sedimentation coefficient (4.2 S) and a large Stokes radius (14.3 nm), indicative of an elongated structure. The Tub4p complex binds Spc110p/Cmd1p via Spc98p and the K(d) for binding is 150 nM. The low nucleation activity of the Tub4p complex is not enhanced when it is bound to Spc110p/Cmd1p, suggesting that it requires additional components or modifications to achieve robust activity. Finally, we report the identification of a large 22 S Tub4p complex in yeast extract that contains multimers of Spc97p similar to gamma-tubulin ring complexes found in higher eukaryotic cells.     

Microtubule organization during zoosporogenesis inAllomyces macrogynus

Summary The microtubule cytoskeleton and cytoplasmic organization ofAllomyces macrogynus during zoosporogenesis was studied using light and electron microscopy. Indirect immunofluorescence methods revealed that the microtubule cytoskeleton progressed through three distinct stages of cytoplasmic distribution during zoospore development. During the first 10 minutes of zoosporogenesis, nuclei were strictly located in the periphery of the cytoplasm, and their associated centrosomes were positioned immediately adjacent to the plasma membrane. Microtubules emanated from centrosomes into the surrounding cytoplasm. Within 20 to 30 min after the induction of zoosporangial cleavage, nuclei migrated to new positions throughout the sporangial cytoplasm and microtubule arrays were primarily organized at and emanated from nuclear surfaces. During the final stage of zoosporogenesis, nuclear envelope-associated microtubules were not observed. Instead, primary organization of cytoplasmic microtubules returned to centrosomes (i.e., basal bodies) and flagella formation was evident. The MPM-2 antibody, which recognizes phosphorylated epitopes of several proteins associated with microtubule nucleation, stained centrosome regions throughout zoosporogenesis but did not stain nuclear envelopes.Abbreviations BSA bovine serum albumin - DAPI 4,6-diamino-2-phenylindole - dH₂O deionized water - DMSO dimethyl sulfoxide - DS dilute salts solution - G/5 0.1% glucose medium - LN₂ liquid nitrogen - LSCM laser scanning confocal microscopy - MTOC microtubule-organizing center - PBS phosphate buffered saline - PCM pericentriolar matrix - TEM transmission electron microscopy - VELM videoenhanced light microscopy