Microtubules and possible microtubule nucleation centers in the cortex of stomatal cells as visualized by high voltage electron microscopy

Summary Thick sections of fixed, embedded stomatal cells ofPhleum pratense were examined using high voltage electron microscopy and stereological procedures. The cortex of guard cells and subsidiary cells throughout differentiation contains numerous microtubules adjacent to the plasmalemma. Although microtubules are usually aligned in one net direction, individual microtubules may diverge from this orientation in various ways, producing anastomosing or crossed arrays. Also present in the cortex of both guard and subsidiary cells are collections of membranous elements and amorphous material upon which microtubules seem to focus, terminate or overlap. Such structures may constitute microtubule nucleation centers. The significance of these observations is discussed in terms of the control of microtubule development, wall microfibril deposition and cell morphogenesis.     

The generation and consolidation of a radial array of cortical microtubules in developing guard cells of Allium cepa L.

The initiation and development of a radial array of microtubules (MTs) in guard cells of A. cepa was studied using immunofluorescence microscopy of tubulin in isolated epidermal layers. Soon after the completion of cytokinesis, MTs originate in the cortex adjacent to a central strip of the new, anticlinically oriented ventral wall separating the two guard cells. Cortical MTs extend from the mid-region of the central strip toward the cell edge where the ventral wall joins the inner periclinal wall. They then spread in a fan-like formation along the periclinal wall and gradually extend along the lateral and end walls as well. Many MTs criss-cross at various angles as they arc past the edge formed by the junction of the ventral and periclinal walls, but they do not terminate there, indicating that, contrary to previous report, the edge is not involved in MT initiation. Instead, the mid-region of the central strip appears to function as a planar MT-organizing zone. Initially, MTs radiate from this zone through the inner cytoplasm as well as the cortex. During cell expansion, however, the cortical MTs increasingly predominate and consolidate into relatively thick, long bundles, while the frequency of non-cortical MTs diminishes. The apparent density of MTs per unit surface area is maintained as the cells expand and gradually flex into an elliptical shape. The guard cells eventually separate completely at the pore site. The entire process is accomplished within about 12 h.Abbreviations DIC differential interference contrast - GC guard cell - MT microtubule To whom correspondence should be addressed.     

Development of the pellicle and thecal plates following ecdysis in the dinoflagellateGlenodinium foliaceum

Summary The ultrastructure and development of the amphiesma of the dinoflagellateGlenodinium foliaceum was studied using conventional electron microscopy and immunocytochemistry. Ecdysis (shedding of the flagella, the outer two membranes of the cell, and the thecal plates) was induced by centrifugation. The cells were resuspended and the thickening of the pellicle and the development of the new thecal vesicles and plates was studied over a 9 h period. After ecdysis, the thin pellicle which underlay the thecal plates in the motile cells thickens to form a complex structure of four distinct layers: an outer layer of randomly oriented fibrils, a 50 nm layer of fibrils oriented perpendicular to the dense layer, the dense layer which has a trilaminate structure, and a wide inner homogeneous layer. The new thecal vesicles form in these pelliculate cells by the migration of electron translucent amphisomal vesicles over the layer of peripheral microtubules to a position directly under the plasmalemma. The thecal vesicles then flatten and elongate. A discontinuous pellicular layer appears within them. Subsequently, the thecal vesicles widen and are filled with a fibrillogranular substance overlying the pelliculate layer. The thecal plates form on top of this fibrillogranular material. By this time, most cells have escaped from the pellicle and are motile. At first, the outer thecal vesicle membrane is continuous with the inner thecal vesicle membrane at the sutures, but when this connection is broken, the dense pelliculate layers become continuous across the suture as does the inner thecal vesicle membrane. At ecdysis, this membrane becomes the new plasmalemma of the cell. Cells at each stage of pellicle thickening and thecal development were labelled with a polydonal antiserum raised against the 70 kDa epiplasmic protein ofEuglena acus. This antiserum labelled both the thecal plates of the motile cells and the inner homogeneous layer of the pellicle of ecdysed non-motile cells. No other amphiesmal structure was labelled, nor was any intracellular compartment.Abbreviations PBS phosphate-buffered saline - PIPES piperazine-N,N-bis[2-ethane sulfonic acid]     

STUDIES ON THE ULTRASTRUCTURE OF THE GUARD CELLS OF OPUNTIA

The guard cells of Opuntia contain numerous mitochondria, elements of endoplasmic reticulum, dictyosomes, and microbodies. A complex array of small to large vacuoles which contain small, membrane-bounded vesicles occur in each guard cell. The variety of cytoplasmic constituents and vacuoles suggest that the guard cells are complex in function. A highly reduced grana-fretwork system within the plastids indicates that the photosynthetic capacity of the guard cells is probably rather low. No plasmodesmata occur in the walls between the guard cells and the subsidiary cells while there are numerous invaginations of the guard cell plasmalemmas. Many of the variations in the plasmalemma probably indicate that the plasmalemma is a highly active interface.     

Morphology ofEntomophthora muscae protoplasts grownin vitro

Summary Entomophthora muscae (C.) Fres. can be grownin vitro as protoplasts. Light and electron microscopical studies of thein vitro developed protoplasts have demonstrated the absence of an organized wall over the protoplasmic Con A-positive membrane at all stages of growth. The cytological organization is typical of the Entomophthorales with condensed chromatin in the interphase nuclei and small eccentric metaphase spindles. Long strands of endoplasmic reticulum, microubules and vesicles surrounding the plasmalemma may be involved in maintaining the precise shape ofE. muscae protoplast. Starvation of the fungus induces the formation of hyphal bodies after deposition of Con A- and WGA-positive wall material at the plasmalemma surface.Abbreviations Con A concanavalin A - DH Drosophila cell culture medium - FITC fluorescein isothiocyanate - GLEN glucose-lactal-bumin-yeast extract-NaCl culture medium for protoplasts - HBL hyphal body-like protoplasts - MM Mitsuhashi and Maramorosch' insect cell culture medium - PATAg periodic acid-thiocarbohydrazide-silver proteinate technique - PBN phosphate buffer with NaCl - S spherical protoplasts - WGA wheat germ agglutinin     

Microbiology in the 1990s: reflections about open questions and trends

The optimal conditions for protoplast formation ofCandida apicola were by using an enzyme fromArthrobacter sp. in combination with 2-mercaptoethanol. The kinetic data support the two-layered structure model of cell wall for this yeast but the structure of the cell wall depended on the age of cells and culture conditions. To regenerate the protoplasts, the type of osmotic stabilizer was important: sorbitol gave 16 to 30% regeneration. Electron microscopy revealed the presence of vesicles in the sections of protoplasts and whole cells ofCandida apicola grown in production medium and producing glycolipids. In sections of whole cells, vesicle-like structures are located in the periplasmic space and in protoplasts they can either be attached to, or released from, the cell surface. These vesicles are thought to be involved in the transport of the surface-active glycolipids and in the protection of the cell against denaturing effects.     

Cellulose microfibril orientation and cell shaping in developing guard cells of Allium: The role of microtubules and ion accumulation

Summary The role of microtubules and ions in cell shaping was investigated in differentiating guard cells of Allium using light and electron microscopy and cytochemistry. Microtubules appear soon after cytokinesis in a discrete zone close to the plasmalemma adjacent to the common wall between guard cells. The microtubules fan out from this zone, which corresponds to the future pore site, towards the other sides of the cell. Soon new cellulose microfibrils are deposited on the wall adjacent to the microtubules and oriented parallel to them. As the wall thickens, the shape of the cell shifts from cylindrical to kidney-like. Studies with polarized light show that guard cells gradually assume a birefringence pattern during development characteristic of wall microfibrils radiating away from the pore site. Retardation increases from 10 Å when cells just begin to take shape, to 80–100 Å at maturity. Both microfibril and microtubule orientation remain constant during development. Observations on aberrant cells including those produced under the influence of drugs such as colchicine, which leads to loss of microtubules, abnormal wall thickenings and disruption of wall birefringence, further support the role of microtubules in cell shaping through their function in the localization of wall deposition and the orientation of cellulose microfibrils in the new wall layer. Potassium first appears in guard mother cells before division and rapidly accumulates afterwards during cell shaping, as judged by the cobaltinitrite reaction. Some chloride and perhaps organic acid anions also accumulate. Thus, these ions, which are known to play a role in the function of mature guard cells, also seem to be important in the early growth and shaping of these cells.Abbreviations IPC isopropyl-N-phenylcarbamate - CB cytochalasin B - GMC guard mother cell - MTOC microtubule organizing center     

Monoclonal antibodies identify common and differentiation-specific antigens on the plasma membrane of guard cells of Vicia faba L.

Monoclonal antibodies were raised against the plasma membrane of Vicia faba L. guard cells by immunizing either with total membranes from purified guard-cell protoplasts or with sealed, predominantly right-side-out plasma-membrane vesicles prepared from abaxial epidermes of V. faba by aqueous two-phase partitioning. Hybridoma screening was performed by enzyme-linked immunosorbent assay using polystyrene-adsorbed plasma-membrane vesicles as solid phase and by indirect immunofluorescence analysis using unfixed, immobilized protoplasts in a microvolume Terasaki assay. A range of monoclonal antibodies was characterized and is reported here. One monoclonal antibody, G26-6-B2, is guard-cell-specific and does not react with mesophyll-cell protoplasts of the same species. It binds to a periodate-resistant but trypsin-labile epitope, probably a differentiation-specific plasma-membrane protein.Abbreviations ELISA enzyme-linked immunosorbent assay - FITC fluorescein isothiocyanate - GCP guard cell protoplast(s) - Ig immunoglobulin - MAB monoclonal antibody - MCP mesophyll-cell protoplast(s) - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis     

Relationships between structure and motility ofAlbizzia motor organs: Changes in ultrastructure of cortical cells during dark-induced closure

Summary Paired leaflets ofAlbizzia julibrissin spread apart (open) in the daytime and fold together (close) at night. We examined the structure of cells in open and closedAlbizzia motor organs (pulvini) to identify reversible changes in structure associated with motility. Pulvini were fixed in glutaraldehyde and stained using conventional methods. The pulvinus has a central vascular cylinder bordered by thick-walled collenchyma cells, in turn surrounded by an endodermis and many layers of cortical parenchyma. Cortical cells in the extensor undergo large changes in shape during leaflet closure linked with: formation of wall infoldings, development of a large periplasmic space filled with fibrils and membranes, development of lobes on the nucleus, evagination of the nuclear outer envelope membrane, break-up of the large central vacuole to form many small vacuoles, and linking of the plasmalemma to inner regions of the cytoplasm by microfilaments. Cortical cells in the flexor, by contrast, remain relatively stable during leaflet movement. Microtubules are present near the plasmalemma in both extensor and flexor cells; in the extensor, spherical coated vesicles are located near the microtubules. The possible function of these structures in regulating intracellular shuttling processes is discussed.     

Ultrastructure of the vegetative organisation and initial stages of silica plate deposition in the soil testate amoebaCorythion dubium

Summary The siliceous body plates ofCorythion dubium are bound by a band of organic cement which is thickest at the lateral margins. The anterior vacuolar cytoplasm is separated by a pigment zone, which forms a dark band in the mid-body region, from the compact posterior region containing a typical vesicular nucleus surrounded by a region of dense endoplasmic reticulum. A pellicular basket of microtubules surrounds the posterior cytoplasm. The large Golgi complex lies between the nucleus and the fundus. Numerous coated and uncoated vesicles from the Golgi cisternae are seen in the peripheral cytoplasm alongside developing plates. These small siliceous plates are enclosed in silicon deposition vesicles lying in surface ruffles of the plasmalemma, often in association with a pair of microtubules. Observations are made on the formation of these vesicles and the early stages of silica deposition. A comparison is drawn between silica deposition inC. dubium and choanoflagellates where there is a similar association between silicon deposition vesicles and microtubules.     

毛竹茎纤维次生壁形成过程的超微结构观察

利用透射电镜观察了毛竹（Ｐｈｙｌｌｏｓｔａｃｈｙｓ ｐｕｂｅｓｃｅｎｓ Ｍａｚｅｌ）茎纤维发育过程中次生壁的形成过程。纤维发育早期,细胞具有较大的细胞核和核仁;细胞质浓稠,具有核糖体、线粒体和高尔基体等细胞器。随着纤维次生壁的形成,细胞壁加厚,细胞质变得稀薄,内质网和高尔基体的数量明显增加,并且两者共同参与了运输小泡的形成;在质膜内侧可观察到大量周质微管分布。随着次生壁的进一步加厚及木质化,细胞壁     

Light- and electron-microscopic studies of growth and reproduction inCutleria (phaeophyta)

Summary Development of the plurilocular male gametangium inCutleria hancockii Dawson is fundamentally similar to that of the female gametangium. However, the sequence of mitoses is less regular and the number of divisions is more variable in the male structure. During mitosis the nucleolus disappears and the nuclear envelope breaks down into vesicles and cisternae. No well-defined chromosomal kinetochores were observed. The spindle does not persist during telophase. At least two types of vesicles, but no microtubules, are associated with cytokinesis. After cleavages are completed, each of the cells develops an eyespot and two flagella. The flagellar rootlet system consists of 4–5 bands of 5–10 microtubules radiating posteriorly from the basal bodies. Flocculent material surrounding the gamete at maturity may be involved with liberation. Prior to release, a pore is formed in each locule when the outermost layers of the surficial wall break, and the innermost layers expand out through this weakened region. The inner wall eventually bursts, releasing the gamete and flocculent material through the pore. The liberated gamete has a long, pleuronematic anterior flagellum, and a short, acronematic posterior flagellum which has a swollen base appressed to the plasmalemma.     

Plasmalemma fine structure in isolated tobacco mesophyll protoplasts

Summary Tobacco mesophyll protoplasts have been examined by electron microscopy during isolation procedures and after 24 hours culture in a medium known to support cell wall regeneration. During isolation the plasmalemma shows little structural differentiation apart from the formation of small vacuoles in the cytoplasm. After 24 hours of culture, several types of activity are seen at the plasmalemma surface. Microtubules, profiles of endoplasmic reticulum, electron dense granules and coated vesicles are associated with the inner surface of the membrane. External to the plasmalemma fibrillar structures occur, both as extensive networks and as individual fibrils apparently associated with the membrane itself. Techniques and criteria for electron microscopy are presented, and the results discussed in terms of plasmalemma function and the regeneration of the cell wall.     

Iron uptake byBifidobacterium thermophilum protoplasts

Protoplasts ofBifidobacterium thermophilum were prepared by a combination of lysozyme and protease digestion, and ferrous iron uptake studies were carried out. Little, if any, iron was internalized by the protoplasts, although large amounts of iron were bound to the protoplast surface. This binding was much greater than that of intact cells, which prefer to internalize iron by an energy-dependent process. It was also found that the binding of iron by protoplasts of cells grown in an iron-deficient medium was much more extensive than that of cells grown in an iron-sufficient medium. Soluble and particulate fractions of protoplasts were prepared by grinding them in a glass homogenizer, and the particulate fraction was also subjected to iron binding studies. The amount of iron bound was the same as that in intact protoplasts, indicating that the particulate fraction membrane fragments bound iron on their outer surface only. Nevertheless, when iron-preloaded cells were protoplasted and their surface cleared of iron, their particulate fraction contained considerable amounts of iron, indicating that the inner surface of the membranes is capable of binding iron as long as the cell is intact. The amount of iron so bound was dose-dependent on the amount of iron entering the cell. The failure of the outer and inner surface iron pools to mix was confirmed by the fact that when iron-preloaded protoplasts were incubated with additional iron, only the latter (surface-bound) was elutable with nonradioactive 2 mM FeSO₄. It is concluded that increasing bifidobacterial iron load increases the amount of iron bound to the inner surface of the membrane; the procedure, which is effective in forming bifidobacterial protoplasts, destroys their iron transport mechanism while uncovering surface iron-binding sites; and that such iron-binding sites may be of significance in the cellular iron metabolism processes.     

The hydraulic conductivity as a criterion for the membrane integrity of protoplasts fused by an electric field pulse

The hydraulic conductivity of the membrane, Lp, of fused plant protoplasts was measured and compared to that for unfused cells, in order to identify possible changes in membrane properties resulting from the fusion process. Fusion was achieved by an electric field pulse which induced breakdown in the membranes of protoplasts in close contact. Close membrane contact was established by dielectrophoresis. In some experiments pronase was added during field application; pronase stabilizes protoplasts against high field pulses and long exposure times to the field. The Lp-values were obtained from the shrinking and swelling kinetics in response to osmotic stress. The Lp-values of fused mesophyll cell protoplasts of Avena sativa L. and of mesophyll and guard cell protoplasts of Vicia faba L. were found to be 1.9±0.9·10^-6, 3.2±2.2·10^-6, and 0.8±0.7·10^-6 cm·bar^-1·s^-1, respectively. Within the limits of error, no changes in the Lp-values of fused protoplasts could be detected in comparison to unfused protoplasts. The Lp-values are in the range of those reported for walled cells of higher plants, as revealed by the pressure probe.Abbreviations GCP guard cell protoplast - Lp hydraulic conductivity - MCP mesophyll cell protoplast     

Microtubule organization and cell division in embryogenie protoplast cultures of white spruce (Picea glauca)

Summary Immunofluorescence methods were developed for examining the distribution of microtubules in freshly isolated and cultured protoplasts and regenerated somatic embryos of white spruce (Picea glauca). Freshly isolated protoplasts consisted of both uniand multinucleate types. Uninucleate protoplasts established parallel cortical microtubules during cell wall formation and cell shaping, divided within 24 h and developed into somatic embryos in culture. Dividing cells were characterized by preprophase bands (PPBs) of microtubules, atypical spindle microtubules focused at the poles and a typical phragmoplast at telophase. Multinucleate protoplasts also established parallel arrays of cortical microtubules during cell wall formation. In addition their nuclei divided synchronously within 4 days, then cell walls formed between the daughter nuclei. Individual multinucleate protoplast-derived colonies subsequently gave rise to elongate suspensor cells thereby forming embryo-like structures by 7 days.     

Microtubule reorganization accompanying preprophase band formation in guard mother cells ofAvena sativa L.

Summary In order to study developmental changes in microtubule organization attending the formation of a longitudinally oriented preprophase band, the guard mother cells ofAvena were examined using a new procedure for anti-tubulin immunocytochemistry on large epidermal segments. We found that the interphase band (IMB) of transverse cortical microtubules present in these cells following asymmetric division is replaced after subsidiary cell formation by mesh-like to radial microtubules that extend throughout the cytoplasm. Many of the Mts are also grouped in bundles. Gradually, this intermediate array is succeeded by longitudinal elements of the PPB. Thus, preprophase band formation is accompanied by a 90° shift in Mt orientation, with a radial arrangement serving as an intermediate stage. The micrographs are most consistent with the rearrangement of intact Mts, although changes in Mt assembly are possible as well. The role of the IMB in guard mother cells is also discussed.Abbreviations GMC guard mother cell - IMB interphase microtubule band - Mt microtubule - PPB preprophase band     

Distribution of microtubules in prolactin cells of lactating rats

The intracellular distribution of microtubules was studied using serial sections of prolactin cells in anterior pituitary glands from lactating rats. Numerous microtubules were present in these cells following fixation with glutaraldehyde and osmium tetroxide. The greatest number of microtubules were present in the Golgi complex, situated around the perimeter and in association with the cisternae, vesicles and developing secretory granules. Microtubules were found in channels between groups of parallel cisternae of rough surfaced endoplasmic reticulum and in close proximity to small vesicles. They were also located adjacent to mitochondria, the plasmalemma, the nuclear envelope, and among mature secretory granules. Due to their orientation within the cell, it is suggested that the microtubules may act to direct the movement of organelles from one region of the cell to another and to give internal support to the cell.     

Studies on isolated starch-containing (Vicia faba) and starch-deficient (Allium cepa) guard cell protoplasts

Guard cell protoplasts from starch-containing Vicia faba and starch-deficient Allium cepa stomata were isolated, stabilized and recovered with an efficiency — in relation to the potential yield — of approx. 62% and 77%, respectively. In vitro, guard cell protoplasts (GCP) respond to abscisic acid and fusicoccin by respectively contracting and swelling, that is, decreasing or increasing in diameter by about 15% and more in comparison to the control. This in vitro response correlates with, but is more than 4 times as rapid as, the in vivo response of the stomata. Among the advantages presented by working with isolated GCPs are: greater sensitivity in response; freedom from influences of cuticular ridges, cell walls, subsidiary cells, and epidermal cells; and direct and parallel comparisons of starch-containing and starch-deficient GCP systems.Abbrecviations ABA abscisic acid - FC fusicoccin - ECP, MCP, and GCP epidermal, mesophyll, and guard cell protoplasts, respectively - PPV packed protoplast volume     

Ultrastructure of the cell wall regeneration of isolated protoplasts of Skimmia japonica thunb

Isolated protoplasts obtained from leaves and from stem callus cultures of Skimmia japonica were cultivated for 72 h to regenerate a new cell wall. During this process the structural changes in the protoplasts and at the surface of the plasmalemma were studied in ultrathin sections and after freeze-fracturing and deep-etching.The cultured protoplasts show an apparent increase in cell organelles compared to the freshly isolated protoplasts. In particular, mitochondria, endoplasmic reticulum, and ribosomes, many of them appear as polysomes, become numerous. Moreover, special connections between the ER and the plasmalemma are visible. Most important are the fracture faces of the plasmalemma with two different arrangements of membrane-bound particles: (1) particles in hexagonal arrays and (2) rows of ca. 14 particles. Their orientation usually conforms with that of the regenerated microfibrils of the cell wall. According to these results the following model for microfibril synthesis and orientation in higher plants is proposed: While the cytoplasmic activity is involved in the production of cellulose precursors and enzymes, the hexagonal arrays may respresent specialized regions for the outward passage of these cellulose precursors. The rows of membrane-associated particles may function as a linear enzyme complex (matrix) for microfibril biosynthesis and orientation.Abbreviations ER endoplasmic reticulum - IAA -indolylacetic acid - 2,4-D 2,4-dichlorophenoxy acetic acid