A light and electron microscope study ofPicea glauca (White spruce) somatic embryos

Summary Somatic embryos in embryogenic callus cultures derived from Immature zygotic embryos ofPicea glauca (White spruce) were examined by light and electron microscopy. Somatic embryos consist of an embryonic region of small densely cytoplasmic cells subtended by a suspensor consisting of long highly vacuolated cells. Mitotic figures are frequent in the embryonic cells but are not observed in the suspensor. Cell divisions in the embryonic region apparently produce rows of cells which elongate to form the suspensor. The presence of abundant polysomes, coated membranes and dictyosomes in the cytoplasm of embryonic and upper suspensor cells suggests rapid growth of the embryo. In contrast the basipetal suspensor cells appear to be senescing. While only a few scattered microfilaments are present in the meristematic cells, the upper suspensor cells contain numerous bundles of longitudinally oriented microfilaments. These bundles correspond to actin cables observed in light microscope preparations stained with rhodamine labelled phalloidin and are oriented parallel to the direction of active streaming in these cells.     

The spermatogenous body cell of the coniferPicea abies (Norway spruce) contains actin microfilaments

Summary In conifer pollen, the generative cell divides into a sterile stalk cell and a body cell, which subsequently divides to produce two sperm. InPicea abies (Norway spruce, Pinaceae) this spermatogenous body cell contains actin microfilaments. Microfilament bundles follow the spherical contour of the body cell within the cell cortex, and also traverse the cytoplasm and enmesh amyloplasts and other organelles. In addition, microfilaments are associated with the surface of the body cell nucleus. The sterile stalk cell also contains microfilament bundles in the cytoplasm, around organelles, and along the nuclear surface. Within the pollen grain, microfilament bundles traverse the vegetative-cell cytoplasm and are enriched in a webbed cage which surrounds the body cell. Microfilaments were identified with rhodamine-phalloidin and with indirect immunofluo-rescence using a monoclonal antibody to actin. The majority of evidence in literature suggests that the spermatogenous generative cell in angiosperms does not contain actin microfilaments, so the presence of microfilaments within the spermatogenous body cell inP. abies appears to be a fundamental difference in sexual reproduction between conifers and angiosperms.     

Nuclear actin bundles in Amoeba, dictyostelium and human HeLa cells induced by dimethyl sulfoxide

In a previous study we demonstrated that dimethyl sulfoxide (DMSO) induces the formation of microfilament bundles in the interphase nucleus of a cellular slime mold, Dictyostelium mucoroides [12], in which the microfilaments bound rabbit skeletal muscle heavy meromyosin, forming an ‘arrowhead’ structure, and that this binding could be reversed by Mg²⁺ and ATP. In the present study, we show electron microscopic data demonstrating the occurrence of such microfilament bundles in the nucleus of Amoeba proteus and human HeLa cells, as well as in D. mucoroides. The similarities in the morphology and dimension of the microfilanets, as well as the specific conditions by which they are induced, suggested that these microfilaments are actin. We present evidence that actin is involved in interphase nucleus of a variety of organisms, and that DMSO acts on the molecules to induce microfilament bundles specifically in the nucleus.     

Microfilament organization and distribution in freeze substituted tobacco plant tissues

Summary The organization and distribution of microfilaments in freze substituted leaf tissues and root tips of tobacco plants (Nicotiana tabacum L. var. Maryland Mammoth) were investigated in detail. Three categories of microfilaments were recognized in interphase cells of all tissues including those in the root cap: (1) microfilament bundles; (2) single microfilaments; (3) cortical microtubuleassociated microfilaments. While the microfilament bundles appeared to be distributed throughout the cytoplasm, the single microfilaments were mainly confined to the cell periphery. All three categories of microfilaments were associated with various organelles. Our study indicates that the three categories of microfilaments are normal cytoskeletal components in higher plant cells. The implications of these findings are discussed.Abbreviations MFB microfilament bundle - SMF single microfilament - MAMF microtubule-associated microfilament - AAP actin-associated protein - MAP microtubule-associated protein - MES 2(N-morpholino)ethanesulfonic acid     

THE EFFECTS OF CYTOCHALASIN B ON THE MICROFILAMENTS OF BABY HAMSTER KIDNEY (BHK-21) CELLS

Attempts were made to test the motile functions of bundles of microfilaments found in baby hamster kidney (BHK-21) cells, by using cytochalasin B (CB). It was found that individual cells respond differently to the drug. These differential effects are quite obvious in both light and electron microscope preparations. Some cells contain normal bundles of microfilaments even after 24 hr in CB, and other cells form muscle-like configurations which also contain arrays of microfilaments. These varied effects suggest the existence of several types of microfilaments in BHK-21 cells, and make the interpretation of the motile role of microfilaments difficult to evaluate at the present time.     

Isolation and characterization of two forms of a cytoskeleton

Isolated petaloid coelomocytes from the sea urchin Strongylocentrotus droebachiensis transform to a filopodial morphology in hypotonic media. Electron micrographs of negatively stained Triton-insoluble cytoskeletons show that the petaloid form consists of a loose net of microfilaments while the filopodial form consists of paracrystalline bundles of microfilaments. Actin is the major protein of both forms of the cytoskeleton. Additional polypeptides have molecular weights of approximately 220,000, 64,000, 57,000, and 27,000 daltons. Relative to actin the filopodial cytoskeletons have an average of 2.5 times as much 57k polypeptide as the petaloid cytoskeletons. Treatment with 0.25 M NaCl dissociates the filament bundles into individual actin filaments free of the actin-associated polypeptides. Thus, one or more of these actin-associated polypeptides may be responsible for crosslinking the actin filaments into bundles and maintaining the three-dimensional nature of the cytoskeletons.     

Microfilament-associated adhering junctions (6 nm F-maculae adherentes) connect bovine pulmonary fibroblasts in vivo

Fibroblasts in the pulmonary alveolar septa of neonatal and mature cattle form spot-shaped intercellular junctions with each other where 6 nm microfilaments adhere to the plasma membranes. The junctions have variable cleft widths (10-20 nm) and a diffuse periodic intracleft substance. Impinging 6 nm microfilaments and plaque specializations were present in thin sections of junctions ranging from 0.4 to 0.6 micron in length. The microfilaments involved in junctions are parts of either cortical cytoplasmic webs or highly organized bundles. Two or more fibroblasts may form one complex of junctions and multiple junctions may occur between two fibroblasts. It is proposed that the in vivo fibroblast junction be named a 6 nm F-macula adherens, based on size of the associated microfilaments and type of junctional specialization.     

The development of myofibrils in cultured muscle cells: A whole-mount and thin-section electron microscopic study

The development of myofibrils in cultured myotome cells from Xenopus embryos was studied with whole-mount and thin-section electron microscopy. For whole mount, the cells were grown on Formvar-coated grids, fixed, dehydrated, critical-point dried, and examined with a conventional (100 kV) or a high-voltage (1000 kV) electron microscope. Nonstriated bundles of 6- to 8-nm microfilaments, similar to stress fibers in nonmuscle cells, appear prior to nascent myofibrils. These bundles run the whole length of the cell and are inserted into the cell cortex. The transition from striated region to nonstriated region on a single nascent myofibril can be seen in both whole-mount and thin-section images. New sarcomeres appear to be added at the distal end of existing ones. Our data also indicate that these new sarcomeres are formed on a preexisting bundle of thin filaments. This suggests that the bundles of microfilaments are precursors to myofibrils. Evidence for this hypothesis came from the following observations. (1) Nascent myofibrils are anchored to the cell cortex via thin filaments similar to microfilament bundles. (2) Thin filaments in newly formed sarcomeres are often continuous through the middle of the A band. Later they break to form the H zone. (3) Thin filaments appear to be continuous through the developing Z band. Later they interact with the filaments in the Z band to form the staggered appearance.     

Improved negative staining of microfilament arrangements in detergent-extracted Physarum amoeboflagellates

A motile, lamellipodium-like structure, the ridge, forms as amoeboflagellate cells of Physarum polycephalum release from a substratum and begin swimming in fluid. Actin microfilaments form a distinct laminar core within the ridge; they are seen as a sparse, disordered meshwork in cytoskeletons prepared by conventional methods using uranyl acetate negative staining [10]. Preservation and visualization of these filaments and their arrangements improved considerably when cytoskeletons were imaged with phosphotungstic acid buffered with ammonium hydroxide (PTA(NH4]. Microfilaments within ridge cytoskeletons were found to form loose bundles and criss-crossing, 'meshwork' arrays several layers deep. Differences could be detected in morphology and detailed arrangement of microfilaments within cytoskeletons prepared in the presence of phalloidin. PTA(NH4) may be useful for studies of cytoskeletal elements and their rearrangements in dynamic, motile regions of cells.     

Organization of the cytoskeleton in pollen tubes ofPyrus communis: a study employing conventional and freeze-substitution electron microscopy,immunofluorescence, and rhodamine-phalloidin

Summary The structure and organization of the cytoskeleton in the vegetative cell of germinated pollen grains and pollen tubes ofPyrus communis was examined at the ultrastructural level via chemical fixation and freeze substitution, and at the light microscopic level with the aid of immunofluorescence of tubulin and rhodamine-phalloidin.Results indicate that cortical microtubules and microfilaments, together with the plasma membrane, form a structurally integrated cytoskeletal complex. Axially aligned microtubules are present in cortical and cytoplasmic regions of the pollen grain portion of the cell and the distal region of the pollen tube portion. Cytoplasmic bundles of microfilaments are found in association with elements of endoplasmic reticulum and vacuoles. Axially aligned microfilaments are also found in this region, associated with and independent of the microtubules. Microtubules are lacking in the subapical region where short, axially aligned microfilaments are found in the cell cortex. In the apical region, which also lacks microtubules, a 3-dimensional network of short microfilaments occurs. Microfilaments, but not microtubules, appear to be associated with the vegetative nucleus.     

The actin microfilament network within elongating pollen tubes of the gymnospermPicea abies (Norway spruce)

Summary Actin microfilaments form a dense network within pollen tubes of the gymnosperm Norway spruce (Picea abies). Microfilaments emanate from within the pollen grain and form long, branching arrays passing through the aperture and down the length of the pollen tube to the tip. Pollen tubes are densely packed with large amyloplasts, which are surrounded by branching microfilament bundles. The vegetative nucleus is suspended within the elongating pollen tube within a complex array of microfilaments oriented both parallel to and perpendicular with the growing axis. Microfilament bundles branch out along the nuclear surface, and some filaments terminate on or emanate from the surface. Microfilaments in the pollen tube tip form a 6 m thick, dense, uniform layer beneath the plasma membrane. This layer ensheathes an actin depleted core which contains cytoplasm and organelles, including small amyloplasts, and extends back 36 m from the tip. Behind the core region, the distinct actin layer is absent as microfilaments are present throughout the pollen tube. Organelle zonation is not always maintained in these conifer pollen tubes. Large amyloplasts will fill the pollen tube up to the growing tip, while the distinct layer of microfilaments and cytoplasm beneath the plasma membrane is maintained. The distinctive microfilament arrangement in the pollen tube tips of this conifer is similar to that seen in tip growth in fungi, ferns and mosses, but has not been reported previously in seed plants.     

Cleavage and membrane formation in the blastoderm of the dipteran Ceratitis capitata wied

In the Ceratitis capitata embryo, furrow formation follows the last mitosis divisions and leads to cellular blastoderm formation. This process displays several interesting features and requires the participation of bundles of microfilaments which are located at the furrow base at the onset of cytokinesis and contract synchronously, determining furrow growth. The new membranes for furrow growth seem to be largely provided by the fusion of many vesicles. Surface projections do not appear to contribute significantly to this phenomenon. At the end of cytokinesis the microfilaments are sandwiched between the plasma membrane and cisternae of endoplasmic reticulum. Subsequently the microfilaments disappear from the cytoplasmic side of the membrane but remain beneath the membranes of the connections and at the periphery of the yolk sack until gastrulation. On the basis of these observations some ultrastructural aspects of furrow formation and the role that the microfilaments may play during this process are discussed.     

Identification of actin in situ at the ectoplasm-endoplasm interface of Nitella. Microfilament-chloroplast association

Using a glycerination procedure designed to avoid excessive plasmolysis or disruption of the ectoplasm, microfilaments in bundles at the ectoplasm-endoplasm interface of Nitella internode cell segments were found to bind rabbit heavy meromyosin (HMM) in situ. All HMM arrowheads in a bundle seem to have the same polarity and many lie in register as judged from the electron micrographs; the arrowhead periodicity is approximately 380 . The decorated microfilaments are thus similar to those seen in negatively stained cytoplasmic suspensions of internode cells. In glycerinated material, as well as in suspensions, the microfilaments are closely associated with chloroplasts. The microfilaments lie adjacent to or are attached to the chloroplast envelope. The results provide further evidence that the microfilaments thought to play a role in cytoplasmic streaming in vivo in Nitella consist of actin and suggest that they may be anchored to the chloroplasts.     

Cortical microtubules and cortical microfilaments in the green alga,Micrasterias pinnatifida

Summary Cortical microtubules and cortical microfilaments were visualized in cells ofMicrasterias pinnatifida treated by freeze-substitution, and the pattern of their distribution was reconstructed from serial sections. Most cortical microtubules accompanied the long microfilaments that ran parallel to the microtubules. Cortical microfilaments not accompanied by the microtubules were also found. They were short and slightly curved. Both types of cortical microfilament were not grouped into bundles, and were 6–7 nm in diameter, a value that corresponds to the diameter of filaments of F-actin.     

Immunofluorescent and ultrastructural studies of polygonal microfilament networks in respreading non-muscle cells

Respreading gerbil fibroma cells (CCL146) have been found to display cytoplasmic actin-based polygonal fiber networks 10 h after replating (stage III of respreading according to Vasiliev & Gelfand, [1]). The networks have been analyzed by immunofluorescence and electron microscopy. The foci, sites of actin, α-actinin and filamin distribution, are condensed meshworks of microfilaments attached to the inner surface of the plasma membrane. The interconnecting fibers, sites of uniform actin distribution and complementary periodicities of α-actinin and myosin, are bundles of parallel microfilaments with periodic dense bodies. Heavy meromyosin (HMM) labelling of the microfilaments in the foci and interconnecting bundles confirm that they contain actin. In addition, approx. 70% of the microfilaments associated with an individual focus have a uniform polarity relative to it (arrowheads pointing away) suggesting that they have their origin there. Our results support earlier conclusions [2] that polygonal networks are structural intermediates responsible for organizing contractile proteins of the cortical microfilament layer into stress fibers.     

THE DISTRIBUTION, ULTRASTRUCTURE, AND CHEMISTRY OF MICROFILAMENTS IN CULTURED CHICK EMBRYO FIBROBLASTS

The distribution, ultrastructure, and chemistry of microfilaments in cultured chick embryo fibroblasts were studied by thin sectioning of flat-embedded untreated and glycerol-extracted cells, histochemical and immunological electron microscopic procedures, and the negative staining of cells cultured on electron microscopic grids. In these cultured cells, the microfilaments are arranged into thick bundles that are disposed longitudinally and in looser arrangements in the fusiform-shaped cells. In the latter case, they are concentrated along the margins of the flattened cell, on the dorsal surface, and particularly at the ends of the cell and its ventral surface, where contact is made with the plastic dish or with other cells. Extracellular filaments, presumably originating from within the cell, are found at these points of contact. The microfilaments are composed in part of an actin-like protein. These filaments are between 70 and 90 Å in diameter, they are stable in 50% glycerol, they have an endogenous ATPase (myosin-like?) associated with them, they bind rabbit muscle heavy meromyosin, and they specifically bind antibody directed against isolated actin-like protein. In the cultured chick embryo fibroblasts, the microfilaments are essential for the establishment and maintenance of form, and they are probably critical elements for adhesion and motility. The microfilaments might also serve as stabilizers of intramembranous particle fluidity.     

The sperm-egg fusion in the nematode Parascaris equorum

Summary

The process of fertilization and the sperm storage in the female apparatus in Parascaris equorum is described in this paper. The sperm approaches the egg by means of pseudopodia containing bundles of microfilaments. The sperm and egg membranes fuse and the sperm penetrates progressively into the ovum. The egg and sperm plasma membranes and glycocalyces disappear at the point of fusion. At the end of fertilization, they are reformed at the egg's surface, while the egg and sperm chromatin begins to decondense. Spermatozoa are stored in the female apparatus prior to fertilization; here they come into contact with the epithelial cells of the spermatheca, protruding pseudopodia rich in microfilaments into the cellular body.     

Intranuclear actin bundles induced by dimethyl sulfoxide in interphase nucleus of Dictyostelium

Electron microscopic evidence demonstrated that dimethyl sulfoxide (DMSO) induces formation of giant intranuclear microfilament bundles in the interphase nucleus of a cellular slime mold, Dictyostelium. These giant bundles are approximately giant bundles are approximately 3 micrometer long, 0.85 micrometer wide, and composed of microfilaments 6 nm in diameter. Studies in which glycerinated cells were used showed that these microfilaments bind rabbit skeletal muscle heavy meromyosin, forming typical decorated "arrowhead" structures, and that this binding can be reverted by Mg-adenosine triphosphate. These data verify that the intranuclear microfilaments are the contractile protein actin, and that DMSO affects intranuclear actin, inducing the formation of such giant bundles. The intranuclear actin bundles appear at any developmental stage in two different species of cellular slime molds after treatment with DMSO. The native form of the intranuclear actin molecules and their possible functions are discussed, and it is proposed that the contractile protein has essential functions in the cell nucleus.     

Actin microfilaments do not form a dense meshwork inLilium longiflorum pollen tube tips

Summary Controversy over whether the apical region of a growing pollen tube contains a dense array of actin microfilaments (MFs) was the impetus for the present study. Microinjection of small amounts of fluorescently labeled phalloidin allowed the observation of MF bundles inLilium longiflorum pollen tubes that were growing and functioning normally. The results show that while the pollen tube contains numerous MF bundles arranged axially, the apical region is essentially devoid of them. The MF bundles could be seen shifting and changing in distribution as the cells grew, but they always remained out of the apical regions. Perturbation of normal growth and function by caffeine causes a change in the MF distribution, which returns to normal upon removal of caffeine from the growth medium. The lack of MFs in the apex is confirmed by careful immunogold electron microscopic analysis of thin sections of rapidly frozen and freeze-substituted pollen tubes, in which very fine MF bundles could be seen somewhat closer to the tip than is discernible with fluorescence microscopy. Still, these are very few in number and are basically absent from the very tip. Thus a reassessment of current assumptions about the distribution of actin in the pollen tube apical region is required.Abbreviations MF microfilaments - FITC fluorescein isothiocyanate - RF-FS rapidly frozen and freeze-substituted - EM electron microscopy Dedicated to Professor Eldon H. Newcomb in recognition of his contributions to cell biology     

Tissue slices from living root caps as a model system in which to study cytodifferentiation of polar cells

Tissue slices of living root caps of cress (Lepidium sativum L.), two to three cell layers in thickness, were prepared by a microsurgical procedure. The viability, cellular structures and cytoplasmic movement of the cells were examined in the light microscope. Nuclei, amyloplasts, vacuoles and endoplasmic reticulum were identified and their positions confirmed after fixation and observation of the same cells in the electron microscope. The distribution of microtubules was shown by immunocytochemistry. During germination, microtubules appear first at the distal edges of the statocytes, while in mature statocytes a distal domain of criss-crossed microtubules could be distinguished from a proximal domain with transversally oriented microtubules. Microfilaments in young statocytes form a nuclear enclosure; in mature statocytes bundles of microfilaments fan out into the cell cortex. The transition from statocytes to secretion cells is accompanied by a more pronounced cortical network of microfilaments, while the nucleus-associated microfilaments remain visible. It is suggested that these microfilaments play a role in the positioning of the nucleus and the translocation of endoplasmic reticulum.Abbreviations ER endoplasmic reticulum - MF microfilament - MT microtubule