Studies on corneal endothelial growth and repair. IV. Changes in the surface during cell division as revealed by scanning electron microscopy

Changes in the surface morphology of regenerating rabbit, rat and frog corneal endothelial cells in vivo have been investigated by scanning electron microscopy. In adult tissue these cells do not normally divide unless given a stimulus, such as injury. Surfaces of quiescent rabbit and rat cells are devoid of microvilli but display globular projections and surface pits up to 300 nm in diameter. However, regenerating endothelia are characterized by the appearance of microvilli which attain their greatest length when the cells are rounded. At this stage, cells also possess filopodia and broad processes. In cytokinesis, the microvilli have shortened and blebs and ruffles appear for the first time. In contrast to rabbits and rats, frog endothelial cells of noninjured tissue are covered by microvilli and smaller surface pits of 60-70 nm diameters. During regeneration, these cells have reduced numbers of microvilli and extensive foldings of the membrane. Neither blebs nor filopodia occur during the mitotic cycle and ruffles are not detected until cytokinesis.     

Filopodia of spreading 3T3 cells. Do they have a substrate-exploring function?

Freshly plated 3T3 cells send out radial projections or filopodia. We observed cells which happended to settle on glass near the borderline of a gold-plated area. When some of the filopodia contacted the gold-plated area and others the glass substratum and remained attached for a few minutes, lamellipodia then extended preferentially toward the gold-plated area. 1-2 h later, most of the cells were found in the gold-plated area. When the filopodia of a spreading 3T3 cell contacted another already spread 3T3 cell and also the glass substratum, the first lamellipodia extended preferentially towards the glass. These observations suggest a directionally differentiated extension of lamellipodia after the filopodia of a spreading 3T3 cell have contacted different substrates in their environment. Before filopodia contact a substrate, they perform a rapid "scanning" motion. Therefore, we suggest that the filopodia of a spreading 3T3 cell serve as organs which explore the nonfluid environment and react to a certain quality of the substrate that is presently unknown. Subsequently, they mediate the extension of lamellipodia into the direction in which this quality is found. The described phenomena are reversibly inhibited by Cytochalasin B at concentrations above 5 mug/ml although filopodia are produced.     

Ultrastructural morphology of ectoplacental cone trophoblasts of hamster embryos.

The invasiveness of trophoblast cells is well known, but it is not clear whether they achieve this property by being transformed to other cell types (like malignant ones) or remain benign. Trophoblasts, in culture, were studied ultrastructurally by examining the surface morphology of the cell vis-à-vis their cytoplasmic outgrowth, and the presence and/or absence of ruffling membranes, filopodia, microvilli, pinocytotic pits or bleb-like structures was observed. Results revealed formation of ruffling membranes only on the leading edge, a presence of slender filopodia and pinocytotic pits but an absence of microvilli and bleb-like structures, the characteristic features of a transformed cell. The study indicated that the trophoblast cells, in spite of being invasive, do not convert to any other cell type.     

Phagocytosis and endocytosis in the colorless flagellate Thaumatomonas lauterborni

Phago- and endocytosis have been studied in the colourless flagellate T. lauterborni using electron microscope. The coated pits are formed on the dorsal surface of the cells and in the flagellar pocket; then they are transformed into coated vesicles and transported into the ventral part of the cell loosing their clathrin coat. The storing of small vesicles in the ventral groove region is constant. To begin to feed a flagellate stops and produces within several seconds long ramified filopodia from the ventral groove. These filopodia serve to phagocyte bacteria. Small ventral vesicles represent the membrane pull which is necessary for a quick formation of the vast surface of filopodia. By means of peroxidase reaction in was shown that these vesicles were of endocytotic origin, rather than being the product of the Golgi apparatus functioning.     

Investigating the limits of filopodial sensing: a brief report using SEM to image the interaction between 10 nm high nano-topography and fibroblast filopodia

Having the ability to control cell behaviour would be of great advantage in tissue engineering. One method of gaining control over cell adhesion, proliferation, guidance and differentiation is use of topography. Whilst it has be known for some time that cells can be guided by micro‐topography, it is only recently becoming clear that cells will respond strongly to nano‐scale topography. The fact that cells will take cues from their micro‐ and nano‐environment suggests that the cells are in some way ‘spatially aware’. It is likely that cells probe the shape of their surroundings using filopodia, and that this initial filopodia/topography interaction may be critical to down‐stream cell reactions to biomaterials, or indeed, the extracellular matrix. One intriguing question is how small a feature can cells sense? In order to investigate the limits of cell sensing, high‐resolution scanning electron microscopy has been used to simultaneously view cell filopodia and 10 nm high nano‐islands. Fluorescence microscopy has also been used to look at adhesion formation. The results showed distinct filopodial/nano‐island interaction and changes in adhesion morphology.     

The very rapid induction of filopodia in insect cells

Many insect cells, including epidermis, fat body, ocnocytcs and pericardial cells, can very easily be induced to form long fine processes or filopodia. Filopodia contain microfilaments hut differ from epidermal feet in lacking microtubules and in having a much smaller and uniform diameter. Although they may be 10-30 mum long they are less than 0.1 mum wide. They often form straight connections like guy-ropes between their origins and their tips, and when freed from their surface attachments they may contract into helices, as though capable of generating tension. The basal lamina helps to keep the basal surfaces of epidermal cells together. In Rhodnius epidermis, filopodia form only seconds after its removal. They arise at the cell margins and extend to distant part of neighbouring cells where they adhere particularly at their tips. Such filopodia retract and disappear in 20-60 min with the reformation of the basal lamina as though they have functioned to pull neighbouring cells back together. In Calpodes epidermis, filopodia form from the lateral faces as well as the cell margins after trypsin digestion of desmosomes and hemidesmosomes. The observations suggest that filopodia are induced in response to cell separation and function to restore cell to cell continuity. Filopodia also form in the normal course of development where cells separate prior to their rearrangement to make new tissues as in epidermal and fat body metamorphosis. Filopodia are probably ubiquitous agents for the sensing and movement of cells relative to one another in tissue morphogenesis.     

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.     

Identification of Caveolae-like Structures on the Surface of Intact Cells Using Scanning Force Microscopy

Caveolae are small, functionally important membrane invaginations found on the surface of many different cell types. Using electron microscopy, caveolae can be unequivocally identified in cell membranes by virtue of their size and the presence of caveolin/VIP22 proteins in the caveolar coat. In this study we have applied for the first time scanning force microscopy (SFM), to visualize caveolae on the surface of living and fixed cells. By scanning the membranes of Chinese hamster ovary cells (CHO), using the tapping mode of the SFM in fluid, we could visualize small membrane pits on the cell membranes of living and fixed cells. Two populations of pits with mean diameters of around 100 nm and 200 nm were present. In addition, the location of many pits visualized with the SFM was coincident with membrane spots fluorescently labeled with a green fluorescent protein-caveolin-1 fusion protein. Scanning force microscopy on cells treated with methyl--cyclodextrin, an agent that sequesters cholesterol and disrupts caveolae, abolished pits with a measured diameter of 100 nm but left pits of around 200 nm diameter intact. Thus, the smallest membrane pits measured with the SFM in CHO cells were indeed very likely to be identical to caveolae. These experiments show for the first time that SFM can be used to visualize caveolae in intact cells.     

Structures in focus--filopodia

Filopodia are thin cell surface extensions filled with tight parallel bundles of actin filaments. They are highly dynamic structures which rapidly extend and retract as well as sweep up and down and from side to side, and can be found at the leading edge of many types of motile cells such as fibroblasts and keratinocytes, as well as the growth cone tips of migrating axons. Cells appear to use filopodia to explore the extracellular matrix (ECM) and surfaces of other cells, identifying appropriate targets for adhesion or in the case of a migrating growth cone, for sensing guidance cues that enable the axon to navigate to it's appropriate target. As well as this sensory role, filopodia have also recently been shown to play an important mechanical role in epithelial adhesion, and are likely to be key players in developmental processes that require migrating epithelial sheets to zipper and fuse to one another. Their dynamic properties as well as their tendency to be damaged or lost after fixation mean they are best analysed using live imaging techniques. As this field improves, the number of tissues in which filopodia are seen to be playing key roles is fast increasing.     

Exclusion of erythrocyte-specific membrane proteins from clathrin- coated pits during differentiation of human erythroleukemic cells

When human erythroleukemic cells are induced to differentiate, they produce globin and redistribute glycophorin and spectrin to one pole of the cell. This process was accompanied by an alteration in the clathrin-coated pits at the cell surface. In nondifferentiating cells, receptors for Concanavalin A have been shown, using electron microscopy, to be concentrated into coated pits and rapidly internalized. Glycophorin was also internalized via coated pits, but was not greatly concentrated into these portions of the surface membrane. Ligands attached to glycophorin were, therefore, cleared from the cell surface more slowly than Concanavalin A. In nondifferentiating cells, immunoelectron microscopy showed that spectrin is largely excluded from coated pits. After erythroid differentiation proceeded for several days, glycophorin was totally excluded from the coated pits along with spectrin. This did not reflect a general cessation of endocytosis, however, because Concanavalin A receptors continued to be internalized. It is possible that the specific exclusion of glycophorin from coated pits is part of the remodeling process that occurs when the precursor cell membrane differentiates into that of the mature erythrocyte.     

Filopodia and adhesion in cancer cell motility

Slender bundled actin containing plasma membrane protrusions, called filopodia, are important for many essential cellular processes like cell adhesion, migration, angiogenesis and the formation of cell-cell contacts. In migrating cells, filopodia are the pioneers at the leading edge which probe the environment for cues. Integrins are cell surface adhesion receptors critically implicated in cell migration and they are transported actively to filopodia tips by an unconventional myosin, myosin-X. Integrin mediated adhesion stabilizes filopodia and promotes cell migration even though integrins are not essential for filopodia initiation. Myosin-X binds also PtdIns(3,4,5)P₃ and this regulates its activation and localization to filopodia. Filopodia stimulate cell migration in many cell types and increased filopodia density has been described in cancer. Furthermore, several proteins implicated in filopodia formation, like fascin, are also relevant for cancer progression. To investigate this further, we performed a meta-analysis of the expression profiles of 10 filopodia-linked genes in human breast cancer. These data implicated that several different filopodia-inducing genes may contribute in a collective manner to cancer progression and the high metastasis rates associated with basal-type breast carcinomas.Key words: filopodia, integrins, migration, cancer     

Protruding membrane nanotubes: attachment of tubular protrusions to adjacent cells by several anchoring junctions

Membrane nanotubes are a morphologically versatile group of membrane structures (some resembling filopodia), usually connecting two closely positioned cells. In this article, we set morphological criteria that distinguish the membrane nanotubes from filopodia, as there is no specific molecular marker known to date that unequivocally differentiates between filopodia and protruding nanotubes. Membrane nanotubes have been extensively studied from the morphological point of view and the transport that can be conducted through them, but little is known about the way they connect to the adjacent cell. Our results show that the nanotubes may connect to a neighboring cell by anchoring junctions. Among cell adhesion proteins, N-cadherin, β-catenin, nectin-2, afadin and the desmosomal protein desmoplakin-2 were immune-labeled. We found that N-cadherin and β-catenin are concentrated in nanotubes, while the concentrations of other junction-involved proteins are not increased in these structures. On the basis of data from transmission electron microscopy, we propose a model of the nanotube attachment where the connection of nanotubes is stabilized by several anchoring junctions, most likely adherens junctions that are formed when the nanotube is sliding along the target cell membrane.     

Scanning electron microscopy of chick epiblast expansion on the vitelline membrane. Cell-substrate interactions

Cell-substrate interactions have been studied by examining migrating edge cells of the expanding chick extraembryonic epiblast on their normal substrate and in culture. Scanning electron microscopy shows that the outer face of the vitelline membrane is a random meshwork of fibrils (80 nm diam). The inner face, which is the normal substrate of epiblast expansion, is composed of a random branched system of fibers (400 nm diam) overlain by a network of fibrils (40 nm diam). The epiblast edge in situ has radially oriented filopodia (20 μm long, 200 nm diam.), frequently extending from broad lamellipodia. Blastoderms cultured on the inner face of unincubated vitelline membrane expand at a normal rate but display ruffles as well as filopodia and lamellipodia. When the blastoderm is cultured on the outer membrane face there is no expansion, but cells leave the edge and migrate across the membrane. In these cultures, ruffles are observed on the ventral epiblast face. Absence of the mass of yolk in culture appears to permit or provoke the observed ruffling. Comparison of dissociated epiblast edge cells and skin epithelial cells, cultured on glass and on the vitelline membrane inner face, indicates that epiblast cells remain flattened and display characteristic filopodia on both substrates, whereas skin cells display ruffles on the vitelline membrane but are flattened on glass. The mode of migration of epiblast edge cells seems to be more dependent on intrinsic factors than that of skin cells.     

Filopodia and adhesion in cancer cell motility

Slender bundled actin containing plasma membrane protrusions, called filopodia, are important for many essential cellular processes like cell adhesion, migration, angiogenesis and the formation of cell-cell contacts. In migrating cells, filopodia are the pioneers at the leading edge which probe the environment for cues. Integrins are cell surface adhesion receptors critically implicated in cell migration and they are transported actively to filopodia tips by an unconventional myosin, myosin-X. Integrin mediated adhesion stabilizes filopodia and promotes cell migration even though integrins are not essential for filopodia initiation. Myosin-X binds also PIP3 and this regulates its activation and localization to filopodia. Filopodia stimulate cell migration in many cell types and increased filopodia density has been described in cancer. Furthermore, several proteins implicated in filopodia formation, like fascin, are also relevant for cancer progression. To investigate this further, we performed a meta-analysis of the expression profiles of 10 filopodia-linked genes in human breast cancer. These data implicated that several different filopodia inducing genes may contribute in a collective manner to cancer progression and the high metastasis rates associated with basal-type breast carcinomas.     

Regulation of surface topography of mouse peritoneal cells. Formation of microvilli and vesiculated pits on omental mesothelial cells by serum and other proteins

The mesothelial cells of the mouse omentum provide an in vivo model for the study of the mobilization of labile microvilli on the cell surface. These mesothelial cells are sparsely covered with microvilli and large pits 150--400 nm in diameter, termed vesiculated pits. On the unstimulated cell, the microvilli average 44/100 microns2 and pits, 30/100 microns 2 of surface and they are rapidly induced to increase in number by the intraperitoneal injection of isologous mouse serum. After 2 min, microvilli increase threefold, continue to sevenfold at 30 min, and decrease to fourfold at 90 min. Vesiculated pits increased with similar kinetics. Bovine serum albumin and gamma globulin also stimulate the microvilli and pits to form, but the response is a slow, gradual rise to five- or sixfold the normal value at 90 min. Evidence indicates that multiple factors, possibly including insulin and immunoglobulins, are involved in the effect of serum. The close physical and temporal relationship between microvilli and pits suggests that a correlation exists in their mobilization by the cell and it is hypothesized that microvilli function in the regulation of the cortical microfilament network in effecting this mobilization.     

Characterization of sea urchin primary mesenchyme cells and spicules during biomineralization in vitro

An in vitro culture system for primary mesenchyme cells of the sea urchin embryo has been used to study the cellular characteristics of skeletal spicule formation. As judged initially by light microscopy, these cells attached to plastic substrata, migrated and fused to form syncytia in which mineral deposits accumulated in the cell bodies and in specialized filopodial templates. Subsequent examination by scanning electron microscopy revealed that the cell bodies and the filopodia and lamellipodia formed spatial associations similar to those seen in the embryo and indicated that the spicule was surrounded by a membrane-limited sheath derived by fusion of the filopodia. The spicules were dissolved from living or fixed cells by a chelator of divalent cations or by lowering the pH of the medium. However, granular deposits found in the cell bodies appeared relatively refractory to such treatments, indicating that they were inaccessible to agents that dissolved the spicules. Use of rapid freezing and an anhydrous fixative to preserve the syncytia for transmission electron microscopy and X-ray microprobe analysis, indicated that electron-dense deposits in the cell bodies contain elements (Ca, Mg and S) common to the spicule. Examination of the spicule cavity after dissolution of the spicule mineral revealed openings in the filopodia-derived sheath, coated pits within the limiting membrane and a residual matrix that stained with ruthenium red. Concanavalin A--gold applied exogenously entered the spicule cavity and bound to matrix glycoproteins. Based on these observations, we conclude that components of the spicule initially are sequestered intracellularly and that spicule elongation occurs in an extracellular cavity. Ca2+ and associated glycoconjugates may be routed in this cavity via a secretory pathway.     

Dynamic activity of the filopodia of sea urchin embryonic cells and their role in directed migration of the primary mesenchyme in vitro

Primary mesenchyme cells used in this study were isolated from Lytechinus pictus mesenchyme blastulae by their ability to preferentially adhere to the surface of a tissue culture dish in the presence of serum. Once isolated, primary mesenchyme cells were found to form thin, elongated, active filopodia which closely resemble the filopodia seen in vivo. The filopodia formed in vitro can move as stiffened bristles, bend gradually or very sharply, or be slowly withdrawn. The integrity of the filopodia is not affected by nocodazole but is totally disrupted by cytochalasin D. Filopodia exhibit several apparent functions in vitro: as organelles involved in contacting the external environment, as anchoring appendages that hold the cell bodies in place, and as intercellular connectives that can join cell bodies. The filopodia of primary mesenchyme cells appear to have similar roles within the embryo. The function of the filopodia has been explored by watching the behavior of isolated primary mesenchyme cells in close proximity to deposits of extracellular material (ECM) prepared from mesenchyme blastulae. When the filopodium from a mesenchyme cell makes contact with the nearby ECM, a response is initiated which causes the cell body to move in a directed manner toward the ECM deposit. The use of this type of response as a model system for the study of the migration of primary mesenchyme cells within the embryo is considered.     

Contact guidance of chick embryo neurons on single scratches in glass and on underlying aligned human skin fibroblasts

The influence of substratum topography on the morphology and orientation of neurites of chick embryo neurons was studied.Two series of experiments are reported. One concerned the behaviour of growth cones when the axons become contact-guided by the surface texture. The second studied contact guidance of neurites extending on a compact layer of fixed aligned human skin fibroblasts (HSF).It was observed that when the growth cones of sensory neurons isolated from dorsal root ganglions encountered a single scratch in a glass surface (0.1-2 microm in depth and diameter) they turned and continued movement following the axis of the scratch. These neurons became contact-guided as a result of the sequence of events. The growth cone filopodia recognized the irregularity in the substratum surface, whereas the growth cone lamella stabilized contact with the scratch and moved forward along the scratch axis. Scanning electron microscope revealed that the single scratches 150 nm in width and ca. 100 nm deep growth cone filopodia less than 200 nm in diameter could detect and react by turning into them. These filopodia extensions followed the edge of scratches. However, phase contrast and Nomarski's differential interference contrast appeared insufficient for analysis of primary contact guidance of fine growth cone filopodia which themselves are often less than 200 nm. In neuron cultures on fixed aligned HSF, the neuron aggregates assumed spindle-like shapes, and sparsely seeded individual neurons extended axons along the long axes of the fibroblasts. The axons extended significantly further on the fixed underlying fibroblasts than on collagen-covered glass. In crowded cultures of neurons, the cells extended neurites ignoring both the surface anisotropy (the scratches) and the orientation of the aligned fibroblasts. Immunofluorescence staining of neurons with antibodies against neurofilaments made it possible to analyse their shape and orientation on the fibroblasts. Computer-assisted image analysis permitted the observed alignment of the neurites to be characterized quantitatively.     

Effect of membrane flow on the capture of receptors by coated pits. Theoretical results.

Coated pits trap cell surface receptors and mediate their internalization. Once internalized, many receptors recycle back to the cell surface. When recycled receptors are inserted into the plasma membrane, they move until they are again trapped in coated pits. The mechanisms for moving receptors from their insertion sites to coated pits are unknown. Unaided diffusion as the transport mechanism is consistent with the observed kinetics of receptor recycling. Another candidate for the transport mechanism is convection. For receptors that recycle to random positions on the cell surface, or to restricted regions about coated pits, we assess the importance of convective flow in the transport of receptors to coated pits. First we consider local flows set up by the formation of coated pits and their transformation into coated vesicles. As coated pits form and round into coated vesicles, surrounding membrane is drawn inward, creating flows directed toward the coated pit centers. We show that unless the lifetime of a coated pit is very short, 10 s or less, such local flows have a negligible effect on the time it takes receptors to reach coated pits. We also show that they are unlikely to be the mechanism that keeps receptors that have reached coated pits trapped within coated pits until they are internalized. Finally we calculate the mean time tau for a diffusing receptor to reach a coated pit in the presence of membrane flow that is constant in magnitude and direction, as may occur on moving cells. We show that for typical membrane flow velocities, tau can be reduced significantly from its value in the absence of flow. For example, a velocity v = 2.8 micron/min cuts the mean transport time in half.     

Comparison of the three-dimensional organization of unextracted and Triton-extracted human neutrophilic polymorphonuclear leukocytes

The three-dimensional organization of the cytoplasm of randomly migrating neutrophils was studied by stereo high-voltage electron microscopy. Examination of whole-mount preparations reveals with unusual clarity the structure of the cytoplasmic ground substance and cytoskeletal organization; similar clarity is not observed in conventional sections. An extensive three-dimensional network of fine filaments (microtrabeculae) approximately 7 to 17 nm in diameter extends throughout the cytoplasm and between the two cell cortices; it also comprises the membrane ruffles and filopodia. The granules are dispersed within the lattice and are surrounded by microtrabeculae. The lattice appears to include dense foci from which the microtrabeculae emerge. Triton X-100 dissolves the plasma membrane, most of the granules, and many of the microtrabecular strands and leaves as a more stable structure a cytoskeletal network composed of various filaments and microtubules. Heavy meromyosin-subfragment 1 (S1) decoration discloses actin filaments as the major filamentous component present in membrane ruffles and filopodia. Actin filaments, extending from the leading edge of the cells, are of uniform polarity, with arrowheads pointing towards the cell body. Likewise, the filaments forming the core of filopodia have the barbed end distal. End-to-side associations of actin filaments as well as fine filaments (2--3 nm) which are not decorated with S1 and link actin filaments are observed. The ventral cell cortex includes numerous substrate-associated dense foci with actin filaments radiating from the dense center. Virtually all the microtubules extend from the centrosome. An average of 35 +/- 7 microtubules originate near the pair of centrioles and radiate towards the cell periphery; microtubule fragments are rare. Intermediate filaments form an open network of single filaments in the perinuclear space. Comparison of Triton-extracted and unextracted cells suggest that many of the filamentous strands seen in unextracted cells have as a core a stable actin filament.