Microfibrillar structure of growing cell wall in a coenocytic green alga,Boergesenia forbesii

A fine structure of cell wall lamellae in a coenocytic green algaBoergesenia forbesii was examined by electron microscopy. The wall has a polylamellate structure containing cellulose microfibrils 25 to 30 nm in diameter. The outer surface of the cell was covered by a thin structureless lamella, underneath which existed a lamella containing randomly-oriented microfibrils. The major part of the wall consisted of two types of lamellae, multifibrillar lamella and a transitional, matrix-rich one. In the former, microfibrils were densely arranged more or less parallel with each other. In the transitional lamella, existing between the multifibrillar ones, the microfibril orientation shifted about 30° within the layer. The fibril orientation also shifted 30° between adjacent transitional and multifibrillar layers, and consequently the microfibril orientation in the neighboring multifibrillar layers shifted 90°. It was concluded that the orientation rotated counterclockwise when observed from inside the cell. Each lamella in the thallus wall become thinner with cell expansion, but no reorientation of microfibrils in the outer old layers was observed. In the rhizoid, the outer lamellae sloughed off with the tip growth.     

Lattice images from ultrathin sections of cellulose microfibrils in the cell wall of Valonia macrophysa Kütz.

The crystalline ultrastructure and orientation of cellulose microfibrils in the cell wall of Valonia macrophysa were investigated by means of high-resolution electron microscopy of ultrathin (approx. 28 nm) sections. With careful selection of imaging conditions, ultrastructural aspects of the cell wall that had remained unresolved in previous studies were worked out by direct imaging of crystal lattice of cellulose microfibrils. It was confirmed that each microfibril is a single crystal having a lateral dimension of 20·20 nm², because lattice images of 0.39 nm resolution were clearly recorded with no major disruption in the whole area of the cross section of the microfibril. There was no evidence for the existence of 3.5-nm elementary fibrils which have been considered to be basic crystallographic and morphological units of cellulose in general. It was also confirmed that the axial directions (crystallographic fiber direction) of adjacent microfibrils in each single lamella of the cell wall are opposite to each other.     

Exocytosis in non-plasmolyzed and plasmolyzed tobacco pollen tubes

Exocytosis occurring during deposition of secondary wall material was studied by freeze-fracturing ultrarapidly frozen non-plasmolyzed and plasmolyzed tobacco pollen tubes. The secondary wall of tobacco pollen tubes shows a random orientation of microfibrils. This was observed directly on fractures through the tube wall and indirectly as imprints of microfibrils on fracture faces of the plasma membrane of non-plasmolyzed tubes. About half of the plasmatic fracture faces from non-plasmolyzed and plasmolyzed pollen tubes carried hexagonal arrays of intramembraneous particles in between randomly distributed particles. Deposition of secondary wall material was often accompanied by an undulated plasma membrane and the presence of membrane-bound vesicles in invaginations of the plasma membrane, between the plasma membrane and secondary wall and-especially in plasmolyzed tubes-within the secondary wall of tube flanks and wall cap. The findings are discussed in connection with published schemes of membrane behaviour during exocytosis.Abbreviations EF extraplasmatic fracture face - IMP(s) intramembraneous particle(s) - PF plasmatic fracture face Extended version of a contribution (poster) presented at the 8th Int. Symp. on Sexual Reproduction in Seed Plants, Ferns and Mosses, Wageningen, The Netherlands, August 1984 Dedicated to Prof. Dr. H.F. Linskens (Nijmegen) on the occasion of his 65th birthday in 1986     

Cell walls,plasma membranes,and dictyosomes during zygote maturation ofClosterium ehrenbergii

Summary The cell wall formation and its correlation with the plasma membrane and dictyosome were investigated by an electron microscope in the zygote cells ofClosterium ehrenbergii. During zygote maturation, six wall layers were formed outside the plasma membrane. Wall layer III was the thickest layer and consisted of microfibril bundles. Dictyosomes produced flat vesicles during formation of wall layer III. Hexagonal arrays of rosette particles appeared in the plasma membrane in this period, thus confirming the simultaneous occurrence of flat vesicles and hexagonal particle arrays in the formation of microfibril bundles even at different stages of the life cycle. Wall layer VI was second in thickness and consisted of single microfibrils. Neither flat vesicles nor hexagonal particle arrays were observed during formation of this layer.     

STABILITY AND COLCHICINE EFFECT OF WALL MICROFIBRILLAR ALIGNMENT IN THE NITELLA RHIZOID

The cell wall of the Nitella rhizoid was stripped to make wedges of various thicknesses. Polarizing and interference microscopes were used to examine the post-deposition orientation of wall microfibrils. The fibrils appeared to maintain alignment after they were deposited. Since during growth the rhizoid wall elements are static in the cylindrical part or extend isotropically in the dome (Chen, 1973), these observations provide indirect evidence that the fibrillar reorientation observed in the Nitella internode is due to a passive reorientation during the predominant longitudinal cell elongation (Gertel and Green, 1977). The static microfibrils of the secondary wall of rhizoid, however, reoriented under the influence of colchicine, the alignment becoming almost random after 48 hrs. The disturbance of alignment started in the region adjacent to the plasma membrane, increasing in thickness with prolonged treatment.     

ULTRASTRUCTURAL ASPECTS OF EARLY STAGES IN COTTON FIBER ELONGATION

Fine structural alterations associated with early stages of cotton fiber elongation in Gossypium hirsutum L. var. dunn 56 C occur rapidly following anthesis and appear to be correlated with the formation of the central vacuole, plasma membrane, and primary cell wall as well as with increased protein synthesis necessary for cell elongation. Association of dilated cisternae of the endoplasmic reticulum with the tonoplast suggests that the endoplasmic reticulum is involved in the formation of the central vacuole. Dictyosome involvement in both plasma membrane and primary cell wall formation was suggested from observations of similarities between dictyosome associated vesicles, containing fibrils appearing similar in morphology to fibrils found in the primary cell wall, and plasma membrane associated vesicles. The single nucleolus found in cotton fibers enlarges following anthesis, shows segregation of granular and fibrillar components by 1 day postanthesis, develops a large “vacuole,” thus appearing ring-shaped, and occupies much of the nuclear volume by 2 days postanthesis. Prominent nucleoli were not observed in nuclei after 10 days postanthesis.     

Plasma-membrane rosettes in root hairs of Equisetum hyemale

Particle arrangement in the plasma membrane during cell wall formation was investigated by means of the double-replica technique in root hairs of Equisetum hyemale. Particle density in the protoplasmic fracture face of the plasma membrane was higher than in the extraplasmic fracture face. Apart from randomly distributed particles, particle rosettes were visible in the PF face of the plasma membrane. The rosettes consisted of six particles arranged in a circle and had an outer diameter of approx. 26 nm. No gradient in the number of rosettes was found, which agrees with micrifibril deposition taking place over the whole hair. The particle rosettes were found individually, which might indicate that they spin out thin microfibrils as found in higher-plant cell walls. Indeed microfibril width in these walls, measured in shadowed preparations, is 8.5±1.5 nm. It is suggested that the rosettes are involved in microfibril synthesis. Non-turgid cells lacked microfibril imprints in the plasma membrane and no particle rosettes were present on their PF face. Fixation with glutaraldehyde caused, probably as a result of plasmolysis, the microfibril imprints to disappear together with the particle rosettes. The PF face of the plasma membrane of non-turgid hairs sometimes showed domains in which the intramembrane particles were aggregated in a hexagonal pattern. Microfibril orientation during deposition will be discussed.Abbreviations EF extraplasmic fracture face - PF protoplasmic fracture face     

Spatial relationship between microtubules and plasma-membrane rosettes during the deposition of primary wall microfibrils in Closterium sp.

The mechanism by which cortical microtubules (MTs) control the orientation of cellulose microfibril deposition in elongating plant cells was investigated in cells of the green alga, Closterium sp., preserved by ultrarapid freezing. Cellulose microfibrils deposited during formation of the primary cell wall are oriented circumferentially, parallel to cortical MTs underlying the plasma membrane. Some of the microfibrils curve away from the prevailing circumferential orientation but then return to it. Freeze-fracture electron microscopy shows short rows of particle rosettes on the P-face of the plasma membrane, also oriented perpendicular to the long axis of the cell. Previous studies of algae and higher plants have provided evidence that such rosettes are involved in the deposition of cellulose microfibrils. The position of the rosettes relative to the underlying MTs was visualized by deep etching, which caused much of the plasma membrane to collapse. Membrane supported by the MTs and small areas around the rosettes resisted collapse. The rosettes were found between, or adjacent to, MTs, not directly on top of them. Rows of rosettes were often at a slight angle to the MTs. Some evidence of a periodic structure connecting the MTs to the plasma membrane was apparent in freeze-etch micrographs. We propose that rosettes are not actively or directly guided by MTs, but instead move within membrane channels delimited by cortical MTs attached to the plasma membrane, propelled by forces derived from the polymerization and crystallization of cellulose microfibrils. More widely spaced MTs presumably allow greater lateral freedom of movement of the rosette complexes and result in a more meandering pattern of deposition of the cellulose fibrils in the cell wall.Abbreviations E-face exoplasmic fracture face - MT microtubule - P-face protoplasmic fracture-face     

Visualization of particle complexes in the plasma membrane of Micrasterias denticulata associated with the formation of cellulose fibrils in primary and secondary cell walls

Highly ordered arrays of intramembrane particles are observed in freeze- fractured plasma membranes of the green alga Micrasterias denticulata during the synthesis of the secondary cell wall. The observable architecture of the complex consists primarily of a precise hexagonal array of from 3 to 175 rosettes, consisting of 6 particles each, which fracture with the P-face. The complexes are observed at the ends of impressions of cellulose fibrils. The distance between rows of rosettes is equal to the center-to-center distance between parallel cellulose fibrils of the secondary wall. Correlation of the structure of the complex with the pattern of deposition indicates that the size of a given fibril is proportional to the number of rosettes engaged in its formation. Vesicles containing hexagonal arrays of rosettes are found in the cytoplasm and can be observed in the process of fusing with the plasma membrane, suggesting that the complexes are first assembled in the cytoplasm and then incorporated into the plasma membrane, where they become active in fibril formation. Single rosettes appear to be responsible for the synthesis of microfibrils during primary wall growth. Similar rosettes have now been detected in a green alga, in fern protonemata, and in higher plant cells. This structure, therefore, probably represents a significant component of the cellulose synthesizing mechanism in a large variety of plant cells.     

Arrays of plasma-membrane “rosettes” involved in cellulose microfibril formation of Spirogyra

The cell-wall structure and plasma-membrane particle arrangement during cell wall formation of the filamentous chlorophycean alga Spirogyra sp. was investigated with the freeze-fracture technique. The cell wall consists of a thick outer slime layer and a multilayered inner wall with ribbon-like microfibrils. This inner wall shows three differing orientations of microfibrils: random orientation on its outside, followed by axial bundles of parallel microfibrils, and several internal layers of bands of mostly five to six parallel associated microfibrils with transverse to oblique orientation. The extraplasmatic fracture face of the plasma membrane shows microfibril imprints, relatively few particles, and “terminal complexes” arranged in a hexagonal package at the end of the imprint of a microfibril band. The plasmatic fracture face of the plasma membrane is rich in particles. In places, it reveals hexagonal arrays of “rosettes”. These rosettes are best demonstrable with the double-replica technique. These findings on rosette arrays of the zygnematacean alga Spirogyra are compared in detail with the published data on the desmidiacean algae Micrasterias and Closterium.     

A helicoidal cell wall texture in root hairs ofLimnobium stoloniferum

Summary The cell wall of root hairs ofLimnobium stoloniferum is composed of two fibrillar layers: an outer layer with a dispersed texture and an inner layer with a helicoidal texture. In stained oblique sections the helicoidal layer appears as a series of bow-shaped structures. In sections which were shadow-casted after the embedding medium was removed, the following properties of the helicoidal layer can be directly observed. (1) It is build up of superimposed lamellae. (2) Each lamella consists of parallel oriented microfibrils. (3) Going into the helicoidal layer, there is a counter-clockwise discontinuous rotation of the microfibril orientation in successive lamellae. (4) Between adjacent lamellae the average angular displacement of the microfibril orientation is about 23 degrees. The dispersed outer layer is also polylamellated, but with randomly arranged microfibrils in each lamella. Both layers are present in the lateral wall as well as in the apical wall of the root hairs. Observations indicate that in the cell wall of the tip the parallel oriented microfibrils of the outermost helicoidal lamellae become distorted towards a dispersed arrangement. The suggestion is made that the dispersed outer layer is derived from the helicoidal layer.     

THE CELL WALL OF COSMARIUM BOTRYTIS12

The cell wall of Cosmarium botrytis was studied through the use of the freeze-etch technique. The cell wall consists of many thin layers. Fracturing along one layer reveals the positioning of the wall sculpturing, wall pores, and wall microfibrils. The individual microfibrils are grouped together in bands of parallel oriented fibrils. The different bands of parallel microfibrils were apparently arranged at random angles with regard to each other. Small particles may also be present in the cell walls. The cell wall pore unit of Cosmarium botrytis was studied through the use of scanning, freeze-etching, and thin sectioning techniques. The pore sheaths, on the outside of the cell wall, form a collar around the mouth of each pore. The pore sheath is composed of needle-like fibrils radiating outward from the pore. A pore channel traverses the cell wall and leads to a complex pore bulb region between the cell wall and the plasmalemma. The pore bulb contains many small fibrils which radiate toward the plasmalemma from a number of net-like fibril layers which in turn merge into a very electron dense region near the base of the pore.     

Microtubule reorganization,cell wall synthesis and establishment of the axis of elongation in regenerating protoplasts of the algaMougeotia

Summary Microtubule reorganization and cell wall deposition have been monitored during the first 30 hours of regeneration of protoplasts of the filamentous green algaMougeotia, using immunofluorescence microscopy to detect microtubules, and the cell-wall stain Tinopal LPW to detect the orientation of cell wall microfibrils. In the cylindrical cells of the alga, cortical microtubules lie in an ordered array, transverse to the long axis of the cells. In newly formed protoplasts, cortical microtubules exhibit some localized order, but within 1 hour microtubules become disordered. However, within 3 to 4 hours, microtubules are reorganized into a highly ordered, symmetrical array centered on two cortical foci. Cell wall synthesis is first detected during early microtubule reorganization. Oriented cell wall microfibrils, co-aligned with the microtubule array, appear subsequent to microtubule reorganization but before cell elongation begins. Most cells elongate in the period between 20 to 30 hours. Elongation is preceded by the aggregation of microtubules into a band intersecting both foci, and transverse to the incipient axis of elongation. The foci subsequently disappear, the microtubule band widens, and microfibrils are deposited in a band which is co-aligned with the band of microtubules. It is proposed that this band of microfibrils restricts lateral expansion of the cells and promotes elongation. Throughout the entire regeneration process inMougeotia, changes in microtubule organization precede and are paralleled by changes in cell wall organization. Protoplast regeneration inMougeotia is therefore a highly ordered process in which the orientation of the rapidly reorganized array of cortical microtubules establishes the future axis of elongation.     

Characterization of fibrous compound of Golgi vesicles in tapetal cells ofDelphinium

Summary It was shown that Golgi structures abundantly appearing in tapetal cells ofDelphinium Ajacis L. developing anthers, prior to meiocytes meiosis, show a fine fibrous material within their vesicles. At the time of the formation of tapetal cell wall this fibrous component, released by an exocytotic process, is incorporated into the cell wall. The membrane of dictyosomes derived vesicles participates in the development of plasma membrane. Fibrous material appears to be morphologically similar to the fibrils of tapetal cell wall; this cell wall gives a positive reaction for cellulose and pectins, as visible in the light microscope. Moreover, the fibrous and pectinase resistant compound of dictyosomes derived vesicles and the fibrils of cell wall disappear partly after cellulase digestion which proves their cellulosic character. On the other hand pectinase treatment as well as ruthenium red staining suggest associated with cellulose pectins within Golgi vesicles.     

Tracheid differentiation in tobacco pith cultures

Summary Sterile pith cultures of Nicotiana tabacum have been induced to form localized regions of differentiating tracheids. These localized regions have been examined by phase, fluorescence, and electron microscopy, and polarization optics. Fixation for electron microscopy was with glutaraldehyde-osmium. The differentiating tracheids develop characteristic thick cell walls which are eventually lignified. The lignifications appear to be uniform throughout the secondary wall and little or no lignin appears to be deposited in the primary walls or intercellular layer. At all stages of secondary wall deposition, the peripheral cytoplasm contains a system of microtubules which form a pattern similar to that of the developing thickenings. Within this system the microtubules are oriented, the direction of orientation mirroring that of the fibrils in the most recently deposited parts of the wall. The observations support the view that the microtubules are somehow involved in microfibril orientation. The microtubules appear to be attached to the plasma membrane which has a triple layered structure. The two electron dense layers of the plasma membrane have a particulate structure. In the differentiating tracheids at regions where secondary wall thickening has not yet been deposited numerous invaginations of the plasma membrane are observed which contain loosely organized fibrillar material. It is suggested that these are areas of localized activity of the plasma membrane and that the enzymes concerned with the final organization of the cellulose microfibrils are situated at the surface of the plasma membrane. Dictyosomes in the differentiation cells give rise to vesicles which contain fibrous material and the contents are incorporated into the cell wall. Numerous profiles characteristic of plasmodesmata are evident in sections of the secondary thickenings.Part of this work was carried out at the Osborne Memorial Laboratories, Yale University.     

Ultrastructural aspects of cell wall synthesis inSpirogyra

Summary Filaments ofSpirogyra were fixed in 2% osmium tetroxide dehydrated in alcohol and embedded in Araldite. The fine structure of cells with regard to wall synthesis was studied. The cell wall was shown to have four layers. The inner one contains microfibrils and is considered to be the cell wall proper. The outer three layers are components of the slime layer. The innermost of these, the second layer of the wall, was shown to be between 1m to 3m and the third 0.3m to 1m. The fourth layer appears as no more than a dark black line measuring 10 nm across. In the cytoplasm two types of vesicles were seen. The largest of these has contents similar in appearance to the slime layer of the wall. This same material was also seen in the large vesicles attached to the Golgi bodies. It is suggested that the smaller vesicles are derived from the larger vesicles and later fuse with the cell membrane. The Golgi bodies were found to be fairly large measuring up to 5m across. Small electron opaque blobs and flecks on the outside of the plasmalemma and in between the microfibrils of the cell wall proper are considered to be mucilage droplets travelling to the slime layer. It cannot be excluded that some of the material of the large vesicles is released directly into the cytoplasm and is transferred without vesicles through the plasma membrane. The negative contrast appearance of the microfibrils seen in the cell wall is thought to be due to the spaces between them being filled with this electron opaque mucilage.Intercisternal rodlets measuring 2.5 nm across were seen in the Golgi bodies.Transverse microtubules were found to occur near the plasmalemma having the same orientation as some of the microfibrils.Lomasome-like structures sometimes with many 5 nm fibrils in their vicinity were seen.     

Tunicamycin Prevents Cellulose Microfibril Formation in Oocystis solitaria

The effect of tunicamycin (TM) on the development of the cell wall in Oocystis solitaria has been investigated. It was found that 10 micromolar TM completely stops the assembly of new microfibrils as observed at the ultrastructural level. During cell wall formation, freeze fracture replicas of the E-face of the plasma membrane reveal two major substructures: the terminal complexes (TC), paired and unpaired, and the microfibril imprints extending from unpaired TCs. In cells treated for 3 hours or longer with TM, the TCs are no longer visible, whereas microfibril imprints are still present. Because of the reported highly selective mode of action of TM, our results implicate a role for lipid-intermediates in cellulose synthesis in O. solitaria. It is assumed that TM prevents the formation of a glycoprotein which probably is a fundamental part of the TCs and may act as a primer for the assembly of the microfibrils.     

An examination of the developing cotton fiber: Wall and plasmalemma

Summary The ultrastructure of developing cotton fibers has been examined using novel modifications of the techniques of surface replication, freeze-etching and thin-sectioning. The fiber surface was found to be coated with a lamellar cuticle, which is stretched and thinned as the fiber elongates. It is marked by bars which run parallel with the fiber long axis. Beneath the cuticle, the outermost microfibrils of the primary wall lie parallel with the fiber axis, while those adjacent to the plasma membrane are transverse. Primary wall microfibrils are present in bundles, disposed in left-handed and right-handed helices, which correspond with the fibrils observed optically. Microfibrils within bundles form in-phase waves, with wavelengths and amplitudes in the ranges 0.3–7 m and 0.01–0.1 m in primary and secondary walls respectively. As elongation proceeds bundles become displaced towards the cell axis. Microfibrils of the secondary wall, disposed around the cell as fast helices, are similarly bundled and wavy (though with a reduced amplitude). In surface-replicas, large (20–30 nm) granules are present on the cytoplasmic face of the wall which probably correspond with 20–40 nm low prominences visible on freeze-etch EF plasma membrane fracture faces. It is proposed that these may be microfibril-synthesizing centers. Plasma membranes fracture such that the membrane-associated-particles segregate 6040 between P and E fracture moieties, but the prominence and total number of these particles is reduced at the stage of secondary wall formation as compared with primary wall formation. Beneath the plasmalemma the axes of microtubules parallel secondary wall microfibril orientation. Cross-bridges, which stain heavily after glutaraldehyde/tannic acid fixation, link microtubules to plasma membrane. The use of butyl benzene to cement fragments of cotton fibers, employed in this work, may prove useful in other freeze-etch studies of long fibers which are readily ruptured during preparation.     

Microtubules do not control orientation of secondary cell wall microfibril deposition inMicrasterias

Summary The influence of the microtubule disorganizing substances amiprophos-methyl (APM) and colchicine on secondary wall formation inMicrasterias denticulata was investigated by the freezeetch technique. The results reveal that neither microtubule inhibitor changes the pattern of microfibril deposition. The application of APM or colchicine also does not cause any structural alterations of the microfibrils or of the protoplasmic (Pf) and the exoplasmic (Ef) fracture face of the plasma membrane, thus indicating that microtubules are not involved in secondary wall formation inM. denticulata. However, since areas of the plasma membrane which collapsed upon freeze-etching are restricted to the Pf-face of cells treated with microtubule inhibitors, cortical microtubules may function as mechanical support during secondary wall formation. In the cortical cytoplasm filamentous structures are found in close spatial relationship and an almost parallel alignment to rosettes of the plasma membrane.     

The role of microtubules and cell-wall deposition in elongation of regenerating protoplasts of Mougeotia

Protoplasts of the filamentous green alga Mougeotia sp. are spherical when isolated and revert to their normal cylindrical cell shape during regeneration of a cell wall. Sections of protoplasts show that cortical microtubules are present at all times but examination of osmotically ruptured protoplasts by negative staining shows that the microtubules are initially free and become progressively cross-bridged to the plasma membrane during the first 3 h of protoplast culture. Cell-wall microfibrils areoobserved within 60 min when protoplasts are returned to growth medium; deposition of microfibrils that is predominantly transverse to the future axis of elongation is detectable after about 6 h of culture. When regenerating protoplasts are treated with either colchicine or isopropyl-N-phenyl carbamate, drugs which interfere with microtubule polymerization, they remain spherical and develop cell walls in which the microfibrils are randomly oriented.