Formation of bundles of microfilaments during spreading of fibroblasts on the substrate

Electron microscopy was used to study the sites of formation of bundles of parallel microfilaments in the early stages of spreading of normal mouse embryo fibroblasts on the substrate. Bundles of microfilaments were not found in suspended cells. Contact of the surface of spherical cells with the substrate was not sufficient for the formation of bundles: these bundles were not seen near the under surface of cells that were already attached to the substrate but had not yet developed cytoplasmic outgrowths at their periphery. Peripheral cytoplasmic outgrowths (microspikes and lamellar processes) attached to the substrate were found to be the only sites of localization of the first bundles of microfilaments seen in the spreading cells. It is suggested that surface and/or cytoplasm of the newly-formed peripheral cytoplasmic outgrowth may have some special properties necessary for the initiation of the development of microfilament bundles.     

Tubulin-specific antibody and the expression of microtubules in 3T3 cells after attachment to a substratum : Further evidence for the polar growth of cytoplasmic microtubules in vivo

Mouse 3T3 cells were allowed to attach to and spread on glass. The expression of cytoplasmic microtubules during the respreading process was monitored by immunofluorescence microscopy using monospecific antibody against tubulin. During radial attachment of the cells a ring of flattened cytoplasm is seen around the nucleus. Cytoplasmic microtubules then enter this spreading ring from the perinuclear region and elongate toward the plasma membrane. At later times microtubules appear perpendicular to the plasma membrane and seem to be in intimate contact with it giving the impression that they “stretch” the cytoplasm. When the cells assume their typical fibroblastic shape numerous microtubules are seen. They traverse the cytoplasm. Some come close to the plasma membrane and some bend to conform to the shape of the cell. Changes in microtubular organization correlate well with changes in cell shape. These results together with our previous observations on the assembly of cytoplasmic microtubules upon recovery from colcemid treatment suggest that microtubules may grow as polar structures from a microtubular organizing center towards the plasma membrane. The hypothesis that cytoplasmic microtubules might confer polarity on the cell is discussed.     

ON THE ROLE OF MICROTUBULES IN MOVEMENT AND ALIGNMENT OF NUCLEI IN VIRUS-INDUCED SYNCYTIA

Infection of baby hamster kidney (BHK21-F) cells with the parainfluenza virus SV5 causes rapid and extensive cell fusion. Time-lapse cinematography shows that when cells fuse, their nuclei migrate straight to the center of the syncytium at rates of 1–2 µ/min. Nuclei are often arranged in long, tightly packed, parallel rows in syncytia derived from the fibroblastic BHK21-F cells. Polarization microscopy shows birefringent material between and parallel to these rows of nuclei, and electron microscopy shows bundles of cytoplasmic microtubules, ~250 A in diameter, and filaments, ~80 A in diameter, parallel to and between the rows of nuclei. Colchicine treatment causes disappearance of microtubules from BHK21-F cells and an apparent increase in the number of 80-A filaments. Although colchicine-treated, SV5-infected cells fuse, their nuclei do not migrate or form rows but remain randomly scattered through the syncytial cytoplasm. Incubation at 4°C does not disrupt microtubules in BHK21-F cells. Rows of nuclei have been isolated from SV5-induced syncytia, and the nuclei in them have been found to be intimately associated with microtubules but not with other cytoplasmic structures. These results suggest that microtubules demarcate cytoplasmic channels through which nuclei migrate and that they may also be involved in the mechanism of nuclear movement.     

Differential Distribution of Posttranslationally Modified Microtubules in Osteoclasts

The differential distribution of microtubules in osteoclasts in culture was examined by using antibodies against acetylated, tyrosinated, or detyrosinated tubulins. Tyrosinated tubulin was found throughout the cytoplasmic microtubules in all cells examined. An expanding protrusion that contained tyrosinated tubulin but none of the detyrosinated or acetylated form was seen in the immature osteoclasts. Detyrosinated or acetylated tubulin was detectable in the peripheral cytoplasm of the mature osteoclasts displaying the loss of the expanding protrusion. Although most of the microtubules were derived from the centrosome, noncentrosomal microtubules were distributed in the expanding protrusion, which was predominantly positive for tyrosinated tubulin. By tracing single microtubules, the authors found that their growing ends were always rich in tyrosinated tubulin subunits. End binding protein 1 bound preferentially to the microtubule ends. Both acetylated and tyrosinated microtubules were shown to be closely associated with podosomes. Microtubules appeared to grow over or into the podosomes; in addition, the growing ends of single microtubules could be observed to target the podosomes. Moreover, a microtubule-associated histone deacetylase 6 was localized in the podosomes of the osteoclast. On the basis of these results, the authors conclude that posttranslational modifications of microtubules may correlate with characteristic changes in podosome dynamics in osteoclasts.     

Taxol-requiring mutant of Chinese hamster ovary cells with impaired mitotic spindle assembly

In the accompanying paper (Cabral, F., 1982, J. Cell. Biol., 97:22-29) we described the isolation and properties of taxol-requiring mutants of Chinese hamster ovary cells. We now show that at least one of these mutants, Tax-18, has an impaired ability to form a spindle apparatus. Immunofluorescence studies using antibodies to tubulin demonstrate that, when incubated in the absence of taxol, Tax-18 forms only a rudimentary spindle with few and shortened microtubules associated with the spindle poles. Furthermore, midbodies were not observed, consistent with an absence of cytokinesis. Essentially normal spindles and midbodies are seen in the presence of taxol. Electron microscopic examination indicates that centrioles and kinetochores are morphologically normal in the mutant strain. Pole-to-kinetochore microtubules were seen but interpolar microtubules were not. Taxol-deprived mutant cells stained with anti-centrosome serum show an elevated centriole content, indicating that the defect in Tax-18 does not affect centriole replication or prevent progression through the cell cycle. Although Tax-18 cells do not form a complete spindle in the absence of taxol, cytoplasmic microtubule assembly occurs in association with microtubule-organizing centers, and microtubules with apparently normal morphology exist throughout the cytoplasm. Observation of chromosome movement indicates that the defect in these cells occurs after prometaphase. These studies demonstrate that the formation of spindle microtubules requires cellular conditions that are different from those required for cytoplasmic microtubule formation. They further show that a normal spindle may be necessary for cytokinesis but not for progress of the cells through the cell cycle.     

Cytotoxic effects of 3-methylindole on alveolar epithelial cells and macrophages: with special reference to microtubular and filamentous assemblies in alveolar type I cells of bovine lung

The alveolar type I cell is a major permeability barrier between the pulmonary interstitium and alveolar spaces and its thin cytoplasmic processes are greatly susceptible to injury. These cells are often observed to undergo progressive vesiculation, vacuolization and desquamation during 3-methylindole (3MI)-induced acute pulmonary edema after oral administration in goats and cattle. The present study describes proliferation of SER and the presence of polymerized tubulin in the form of microtubules arranged in large bundles shown at ultrastructural level as well as with immunofluorescence staining for tubulin in alveolar type I cells 72 hours after 3MI treatment. Such changes were not seen in pulmonary endothelial cells, alveolar type II cells, alveolar macrophages and neutrophils. The possible role of microtubules in alveolar type I cells as a mechanistic support to resist disruption against the forces of interstitial and alveolar edema is compared with alveolar type II cells, alveolar macrophages and neutrophils. The latter cells undergo dynamic movements in response to inflammatory stimuli and therefore did not show microtubules in their cytoplasm.     

Plant nuclei can contain extensive grooves and invaginations

Plant cells can exhibit highly complex nuclear organization. Through dye-labeling experiments in untransformed onion epidermal and tobacco culture cells and through the expression of green fluorescent protein targeted to either the nucleus or the lumen of the endoplasmic reticulum/nuclear envelope in these cells, we have visualized deep grooves and invaginations into the large nuclei of these cells. In onion, these structures, which are similar to invaginations seen in some animal cells, form tubular or planelike infoldings of the nuclear envelope. Both grooves and invaginations are stable structures, and both have cytoplasmic cores containing actin bundles that can support cytoplasmic streaming. In dividing tobacco cells, invaginations seem to form during cell division, possibly from strands of the endoplasmic reticulum trapped in the reforming nucleus. The substantial increase in nuclear surface area resulting from these grooves and invaginations, their apparent preference for association with nucleoli, and the presence in them of actin bundles that support vesicle motility suggest that the structures might function both in mRNA export from the nucleus and in protein import from the cytoplasm to the nucleus.     

Microtubule independent vesiculation of Golgi membranes and the reassembly of vesicles into Golgi stacks

We have recently shown that ilimaquinone (IQ) causes the breakdown of Golgi membranes into small vesicles (VGMs for vesiculated Golgi membranes) and inhibits vesicular protein transport between successive Golgi cisternae (Takizawa et al., 1993). While other intracellular organelles, intermediate filaments, and actin filaments are not affected, we have found that cytoplasmic microtubules are depolymerized by IQ treatment of NRK cells. We provide evidence that IQ breaks down Golgi membranes regardless of the state of cytoplasmic microtubules. This is evident from our findings that Golgi membranes break down with IQ treatment in the presence of taxol stabilized microtubules. Moreover, in cells where the microtubules are first depolymerized by microtubule disrupting agents which cause the Golgi stacks to separate from one another and scatter throughout the cytoplasm, treatment with IQ causes further breakdown of these Golgi stacks into VGMs. Thus, IQ breaks down Golgi membranes independently of its effect on cytoplasmic microtubules. Upon removal of IQ from NRK cells, both microtubules and Golgi membranes reassemble. The reassembly of Golgi membranes, however, takes place in two sequential steps: the first is a microtubule independent process in which the VGMs fuse together to form stacks of Golgi cisternae. This step is followed by a microtubule-dependent process by which the Golgi stacks are carried to their perinuclear location in the cell. In addition, we have found that IQ has no effect on the structural organization of Golgi membranes at 16 degrees C. However, VGMs generated by IQ are capable of fusing and assembling into stacks of Golgi cisternae at 16 degrees C. This is in contrast to the cells recovering from BFA treatment where, after removal of BFA at 16 degrees C, resident Golgi enzymes fail to exit the ER, a process presumed to require the formation of vesicles. We propose that at 16 degrees C there may be general inhibition in the process of vesicle formation, whereas the process of vesicle fusion is not affected.     

Cytoskeletal arrays in the cells of soybean root nodules: The role of actin microfilaments in the organisation of symbiosomes

Summary Within the infected cells of root nodules there is evidence of stratification and organisation of symbiosomes and other organelles. This organisation is likely to be important for the efficient exchange of nutrients and metabolites during functioning of the nodules. Using immunocytochemical labelling and confocal microscopy we have determined the organisation of cytoskeletal elements, micro tubules and actin microfilaments in soybean nodule cells, with a view to assessing their possible role in organelle distribution. Most microtubule arrays occurred in the cell cortex where they formed disorganised arrays in both uninfected and infected cells from mature nodules. In infected cells from developing nodules, parallel arrays of microtubules, transverse to the long axis of the cell, were observed. In incipient nodules, before release of rhizobia into the plant cells, the cells also had an array of microtubules which radiated from the nucleus into the cytoplasm. Three actin arrays were identified in the infected cells of mature nodules: an aster-like array which emanated from the surface of the nucleus, a cortical array which had an arrangement similar to that of the cortical microtubules, and, throughout the cytoplasm, an array of fine filaments which had a honeycomb arrangement consistent with a distribution between adjacent symbiosomes. Uninfected cells from mature nodules had only a random cortical array of actin filaments. In incipient nodules, the density of actin microfilaments associated with the nucleus and radiating through the cytoplasm was much less than that seen in mature infected cells. The cortical array of actin also differed, being composed of swirling configurations of filaments. After invasion of nodule cells by the rhizobia, the number of actin filaments emanating from the nucleus increased markedly and formed a network through the cytoplasm. Conversely, the cytoplasmic array in uninfected cells of developing nodules was identical to that in the cells of incipient nodules. The cytoplasmic network in infected cells of developing nodules is likely to be the precursor of the honeycomb array seen in mature nodule cells. We propose that this actin array plays a role in the spatial organisation of symbiosomes and that the microtubules are involved in the localisation of mitochondria and plastids at the cell periphery in the infected cells of root nodules.     

MICROTUBULES IN THE FORMATION AND DEVELOPMENT OF THE PRIMARY MESENCHYME IN ARBACIA PUNCTULATA : I. The Distribution of Microtubules

Prior to gastrulation, the microtubules in the presumptive primary mesenchyme cells appear to diverge from points (satellites) in close association with the basal body of the cilium; from here most of the microtubules extend basally down the lateral margins of the cell. As these cells begin their migration into the blastocoel, they lose their cilia and adopt a spherical form. At the center of these newly formed mesenchyme cells is a centriole on which the microtubules directly converge and from which they radiate in all directions. Later these same cells develop slender pseudopodia containing large numbers of microtubules; the pseudopodia come into contact and fuse to form a "cable" of cytoplasm. Microtubules are now distributed parallel to the long axis of the cable and parallel to the stalks which connect the cell bodies of the mesenchyme cells to the cable. Microtubules are no longer connected to the centrioles in the cell bodies. On the basis of these observations we suggest that microtubules are a morphological expression of a framework which opeartes to shape cells. Since at each stage in the developmental sequence microtubules appear to originate (or insert) on different sites in the cytoplasm, the possibility is discussed that these sites may ultimately control the distribution of the microtubules and thus the developmental sequence of form changes.     

The ultrastructure of the cornea-lens epidermis in the lateral eye of Limulus polyphemus

The structure of the “Corneagen,” i.e., the epidermis lying beneath the cornea-lens of the lateral eyes of the adult intermolt Limulus polyphemus was studied with light and electron microscopy. This layer is composed of heavily columnar cells containing a striking number of cytoplasmic microtubules. Many of the microtubules are grouped into compact bundles or fascicles, generally each cell having at least one microtubule bundle. The cornealens end of each cell has numerous microvilli, each with a core of delicate filaments. The crypts between microvilli end in extracellular expansions and plaques of electron dense amorphous material are associated with these terminal expansions. Cytoplasmic microtubules appear to insert into these dense areas. The basal ends of the cells are thrown into many pseudopodial processes which extend into the surrounding extracellular space. The cytoplasm of the pseudopodia is composed largely of microtubules and their associated low density halos. Junctional complexes consisting of zonulae adhaerens and septate desmosomes are present between adjacent cells. Mitochondria, ER, cytoplasmic vesicles, Golgi stacks and other ultrastructural details of the epidermal cells are described. The ultrastructure of a column of pigment free processes lying between the apex of the lens cone and the underlying photoreceptive portion of the ommatidium is also described. Ducts or vessels of uncertain origin are present in the inter-ommatidial spaces. Possible roles played by the microtubules, the significance of their disposition and of their association with the dense subsurface plaques are discussed in terms of intracellular support, epidermis-lens attachment and extracellular pattern determination. In addition, the likelihood of the dense plaques being the site of microtubule assembly is considered.     

Migration Behavior of Granule Cell Neurons in Cerebellar Cultures. II. An Electron Microscopic Study

We examined the fine structure of migrating granule cell neurons in cerebellar microexplant cultures. Radially migrating bipolar cells extended microspikes or small filopodia from their soma and processes and frequently made contact with neighboring cells. These microspikes contained microfilaments but no microtubules. At the later phase of the migration, in which they had symmetrical bipolar long processes, filopodia extending from perikarial region of cells contained microtubules, suggesting that they are precursors of the future thick perpendicular processes. When cell bodies changed orientation from radial to perpendicular, microtubules that were nucleated from perinuclear centrioles frequently extended into both thick radial and perpendicular processes from the perikarial region. Bundles of 10nm intermediate filaments also appeared in these processes. During migration by the perpendicular contact guidance, many filopodia extending from both the thick leading processes and thin trailing processes made close contacts with the radial parallel neurite. These findings suggest that; 1) The direct contact of the filopodia from both the growth cones and their processes of the granule cells to the neurite bundle plays roles in both the parallel and perpendicular contact guidances. 2) The spacial and temporal changes of cytoskeletons and the association of microtubules with perinuclear centrioles are important for the formation of perpendicular processes and initiation of the perpendicular contact guidance.     

Organization of the cytoskeleton in early Drosophila embryos

The cytoskeleton of early, non-cellularized Drosophila embryos has been examined by indirect immunofluorescence techniques, using whole mounts to visualize the cortical cytoplasm and sections to visualize the interior. Before the completion of outward nuclear migration at nuclear cycle 10, both actin filaments and microtubules are concentrated in a uniform surface layer a few micrometers deep, while a network of microtubules surrounds each of the nuclei in the embryo interior. These two filament-rich regions in the early embryo correspond to special regions of cytoplasm that tend to exclude cytoplasmic particles in light micrographs of histological sections. After the nuclei in the interior migrate to the cell surface and form the syncytial blastoderm, each nucleus is seen to be surrounded by its own domain of filament-rich cytoplasm, into which the cytoskeletal proteins of the original surface layer have presumably been incorporated. At interphase, the microtubules seem to be organized from the centrosome directly above each nucleus, extending to a depth of at least 40 microns throughout the cortical region of cytoplasm (the periplasm). During this stage of the cell cycle, there is also an actin "cap" underlying the plasma membrane immediately above each nucleus. As each nucleus enters mitosis, the centrosome splits and the microtubules are rearranged to form a mitotic spindle. The actin underlying the plasma membrane spreads out, and closely spaced adjacent spindles become separated by transient membrane furrows that are associated with a continuous actin filament-rich layer. Thus, each nucleus in the syncytial blastoderm is surrounded by its own individualized region of the cytoplasm, despite the fact that it shares a single cytoplasmic compartment with thousands of other nuclei.     

On the ultrastructure of differentiating secondary xylem in willow

Summary Studies of differentiating xylem inSalix fragilis L. show the immediate cambial derivatives to be ultrastructurally similar. The Golgi apparatus is important at all stages of wall synthesis, possibly producing (amongst other substances) hemicellulose material which is carried to the wall in vesicles or multivesicular bodies. The endoplasmic reticulum also contributes one or more components to the developing wall: at some stages during differentiation the endoplasmic reticulum produces electron opaque bodies which appear to be guided towards the wall by microtubules. Compact structures formed from concentric membranes (myelin-like bodies) have been found joined to rough endoplasmic reticulum, but their presence is not explained.Two types of plasmalemma elaboration occur: invagination of the plasmalemma itself to form vesicles which may contain cytoplasmic material; and vesicles between the plasmalemma and cell wall which are the result of single vesicles or multivesicular bodies traversing the plasmalemma. Both systems provide a means for transporting cytoplasmic material across the plasmalemma.Microtubules have been seen associated with all vesicles derived from the cytoplasm which appear to be moving towards the wall. The presence of microtubules may generally be explained in terms of orientation of vesicles, even if they also happen coincidentally to parallel the supposed orientation of microfibrils in the wall itself. It is possible to resolve connections between the microtubules and the plasmalemma.     

Associations between microbodies and a system of cytoplasmic tubules in oil-body cells of Marchantia

Summary Preliminary observations on differentiating oil-body cells of Marchantia sp. revealed that the cytoplasm possesses conventional cytoplasmic microtubules as well as a greater number of other tubules, which average 35 nm in diameter and appear in cytoplasmic regions rich in endoplasmic reticulum. These tubules, at a stage of active synthesis of oil, increase in number, may form well-organized bundles traversing the cytoplasm close to the vacuole, and show a preferential spatial relationship to elongated microbodies. One layer of densely arrayed cytoplasmic tubules surrounds the microbodies partially or totally. Fine links bridge the tubules to one another or some of them to the microbody bounding membrane.     

The structure of cytoplasm in directly frozen cultured cells. II. Cytoplasmic domains associated with organelle movements

The relationship between organelle movement and cytoplasmic structure in cultured fibroblasts or epithelial cells was studied using video-enhanced differential interference contrast microscopy and electron microscopy of directly frozen whole mounts. Two functional cytoplasmic domains are characterized by these techniques. A central domain rich in microtubules is associated with directed as well as Brownian movements of organelles, while a surrounding domain rich in f-actin supports directed but often intermittent organelle movements more distally along small but distinct individual microtubule tracks. Differences in the organization of the cytoplasm near microtubules may explain why organelle movements are typically continuous in central regions but usually intermittent along the small tracks through the periphery. The central type of cytoplasm has a looser cytoskeletal meshwork than the peripheral cytoplasm which might, therefore, interfere less frequently with organelles moving along microtubules there.     

The presence of extended phragmosomes containing cytoskeletal elements in fusiform cambial cells ofFraxinus excelsior L.

Summary Fusiform cambial cells of the ash (Fraxinus excelsior L.), which are strongly elongated and vacuolated, contain a phragmosome which traverses the whole length of the cells during preprophase and karyokinesis and which remains present during cytokinesis until it is integrated in cell plate with adjacent cytoplasm.The phragmosome consists of a thin perforated cytoplasmic layer located in the plane of the future cell plate. Otherwise oriented transvacuolar cytoplasmic layers or strands are not present in these cells.The phragmosome contains cytoskeletal elements, namely microtubules and also microfilament bundles both of which are oriented mainly in longitudinal direction.The phragmosomal microtubules are a new category of microtubules associated with cell division; presumably they guide the centrifugally growing cell plate to the parental cell wall site previously marked by the preprophase band of microtubules.     

Distribution and orientation of microtubules in milk secreting epithelial cells of rat mammary gland

Summary Quantitative ultrastructural analysis of mid-lactation rat mammary gland demonstrated that cytoplasmic microtubules were present in nearly all secretory epithelial cells examined. Most microtubules were oriented perpendicular to the apical membrane and were found in the apical and medial portions of the cell cytoplasm. There was no statistical difference between the number of microtubules associated with vesicles and the number that were not. Most vesicles which were in contact with microtubules were small (50 to 150 nm), appeared electron lucent and were located in a supra-Golgi complex position. Many of these vesicles were seen to be aligned along the axis of longitudinally sectioned microtubules oriented perpendicular to the apical plasma membrane. As measured by a colchicine binding assay, the total tubulin content of mammary tissue from mid-lactation rats was about 107 g/100 mg wet weight. Approximately 19% of the total tubulin was in polymerized form. This study provides evidence that microtubules may be involved in guiding transport of small secretory vesicles to the apical regions of cells for exocytosis.     

Relocation and reorganization of germ plasm in Xenopus embryos after fertilization

In the unfertilized egg, germ plasm is widely distributed throughout the vegetal subcortex in small islets. Following fertilization or artificial activation, the location and organization changes, and by the 4- to 8-cell stage the germ plasm forms a small number of large patches overlying the vegetal pole. We distinguish three processes that produce these changes. The first of these is aggregation which involves the islets moving towards the vegetal pole to form large patches by coalescence. This phase requires microtubules but does not depend on cleavage or dynamic microfilaments. The second phase is ingression during which the patches of germ plasm move to the interior of the egg. The movement is due to a flow of cytoplasm from the vegetal pole internally and the cytoplasmic current does not require either microtubules or dynamic microfilaments. In the third phase, the germ plasm is trapped in the vegetal hemisphere by microtubular arrays--in normal development, the mitotic spindle.     

Functions of cytoplasmic fibers in intracellular movements in BHK-21 cells

After trypsinization and replating, BHK-21 cells spread and change shape from a rounded to a fibroblastic form. Time-lapse movies of spreading cells reveal that organelles are redistributed by saltatory movements from a juxtanuclear position into the expanding regions of cytoplasm. Bidirectional saltations are seen along the long axes of fully spread cells. As the spreading process progresses, the pattern of saltatory movements changes and the average speed of saltations increases from 1.7 MICROMETER/S during the early stages of spreading to 2.3 micrometer/s in fully spread cells. Correlative electron microscope studies indicate that the patterns of saltatory movements that lead to the redistribution of organelles during spreading are closely related to changes in the degree of assembly, organization, and distribution of microtubules and 10-nm filaments. Colchicine (10 microgram/ml of culture medium) reversibly disassembles the microtubule-10-nm filament complexes which form during cell spreading. This treatment results in the disappearance of microtubules and the appearance of a juxtanuclear accumulation of 10-nm filaments. These changes closely parallel an inhibition of saltatory movements. Within 30 min after the addition of the colchicine, pseudopod-like extensions form rapidly at the cell periphery, and adjacent organelles are seen to stream into them. The pseudopods contain extensive arrays of actinlike microfilament bundles which bind skeletal-muscle heavy meromyosin (HMM). Therefore, in the presence of colchicine, intracellular movements are altered from a normal saltatory pattern into a pattern reminiscent of the type of cytoplasmic streaming seen in amoeboid organisms. The streaming may reflect either the activity or the contractility of submembranous microfilament bundles. Streaming activity is not seen in cells containing well-organized microtubule-10-nm filament complexes.