Three dimensional fine structure of cultured cells: possible implications for subcellular motility

Structural Organization of Detergent-Extracted Cells

Adequate visualization of the three-dimensional organization has always been a major problem in studies of cell architecture. Efforts of numerous investigators weredevoted to the question of how best information can be collected from specimens prepared with different procedures. In recent years, the potential of high voltage electron microscopy has been combined with a technique for sample preparation that circumvents embedding, namely critical point-drying from CO2, to study the three-dimensional fine structure of cells in culture. This approach has revealed new insights into the structural organization of the cytoplasm (1-4). A system of slender strands or microtrabeculae has been described to form an elaborate three-dimensional lattice in which other organelles are embedded. This system has been shown in some cells to undergo rapid conformational changes (3,5) and in general is believed to be an important component of the cytoskeleton, being responsible for the gelatious properties of the cytoplasm.

What we have learned and will learn from cell ultrastructure in embedment-free section electron microscopy

The limitations inherent in conventional electron microscopy (EM) using epoxy ultrathin sections for a clear recognition of biological entities having electron densities similar to or lower than that of epoxy resin have led to the development of embedment-free sectioning for EM. Embedment-free section EM is reliably performed using water-soluble polyethylene glycol (PEG) as a transient embedding medium, with subsequent de-embedment of PEG by immersion into water, followed by critical point-drying (CPD) of the embedment-free section. The present author has stressed that this approach clearly discloses structures whose contours and/or appearance are accordingly vague and/or fuzzy in conventional EM, but does not reveal any new structures. Based on embedment-free electron microscopy (PEG-EM), this article presents five major findings regarding strand- or microtrabecular lattices which have been clearly revealed to occur in the cytoplasmic matrix-an impossibility with conventional EM. These are (1) the appearance of lattices of different compactness in various cells and in intracellular domains of a given cell; (2) the faithful reproduction from an albumin solution in vitro of strand-lattices with correspondingly increasing compactness following increasing concentrations; (3) the appearance of more compact lattices from gelated gelatin than from solated gelatin at a given concentration in vitro; (4) the appearance of either greater or less lattice-compactness by hyper- or hypotonic pretreatments of cells; and (5) the appearance of certain intracellular proteins confined to the centripetal demilune-domain of centrifuged ganglion cells which is occupied with strand-lattices of a substantial compactness. From these findings, questions now arise as to the biological significance of the individual strand itself in the microtrabecular lattices in PEG-EM. In addition, it may be that the appearance of strand-lattices in a given biological domain represents the presence of soluble proteins; the lattice-compactness indicates the concentration of soluble proteins in the domain, and the aqueous cytoplasm is equivalent to the aqueous solution. Further, the appearance of two contiguous lattice domains exhibiting differing degrees of compactness in a given cell indicates that cytoplasmic proteins are solated in a domain with less compact lattices, whereas they are gelated in the other domain. These proposed interpretations need to be confirmed by further studies. If confirmed, the control mechanisms of the localization and movement of intracellular organelles could then be understood on the basis not only of information about the cytoskeletons but also of cell ultrastructure-related information on the concentration and sol-gel states of intracellular proteins. In addition, possible interpretations of the significance of strand-lattices in PEG-EM are also applicable to the nucleoplasm, especially extra-heterochromatin (euchromatin) areas. Finally, several potential uses/advantages of PEG-EM in the cell-ultrastructure have also been demonstrated, especially in three-dimensional reconstructions of nonmembranous structures including stereo-viewing using a pair of EM images with appropriate tilting as well as electron microscopic tomography.

Recurring views on the structure and function of the cytoskeleton: a 300-year epic

Some unnoticed or seldom remembered precedents of current views on biological motion and its structural bases are briefly outlined, followed by a concise recapitulation of how the present theory has been constructed in the last few decades. It is shown that the evolution of the concept of fibers as main constituents of living matter led to hypothesizing microscopic structures closely resembling microtubules in the 18th century. At the beginning of this period, fibers sliding over each other and driven by interposed moving elements were envisioned as the cause of muscle contraction. In the following century, an account of the mechanism of myofibril contraction visualized longitudinal displacements of myosin-containing submicroscopic rodlets. The existence of fibrils in the protoplasm of non-muscle cells, a subject of long debate in the second half of the 19th century, was virtually discarded as irrelevant or fallacious 100 years ago. The issue resurfaced in the early 1930s as a theoretical notion--the cytosquelette--nearly two decades before intracellular filamentous structures were first observed with electron microscopy. The role originally assumed for such fibrils as signal conductors is nowadays being reappraised, although under new interpretations with a much wider significance including modulation of gene expression, morphogenesis, and even consciousness. Since all of the above ancestral conceptions were eventually abandoned, the corresponding current views are, to a certain extent, recurrent.

Visualising the actin cytoskeleton

The actin cytoskeleton is a dynamic filamentous network whose formation and remodeling underlies the fundamental processes of cell motility and shape determination. To serve these roles, different compartments of the actin cytoskeleton engage in forming specific coupling sites between neighbouring cells and with the underlying matrix, which themselves serve signal transducing functions. In this review, we focus on methods used to visualise the actin cytoskeleton and its dynamics, embracing the use of proteins tagged with conventional fluorophores and green fluorescent protein. Included also is a comparison of cooled CCD technology, confocal and 2-photon fluorescence microscopy of living and fixed cells, as well as a critique of current procedures for electron microscopy.

Possible continuity of subplasmalemmal cytoplasmic network with basement membrane cord network: ultrastructural study

The ultrastructure of the subplasmalemmal cytoplasm of the cell and the associated basement membrane as well as the area of the cell-basement membrane border were observed with high resolution electron microscopy after preparation of the tissues with cryofixation or glutaraldehyde fixation followed by freeze substitution. The subplasmalemmal cytoplasm of the smooth muscle cells of rat epididymal tubules and the podocyte processes of the mouse glomerular visceral epithelium were found to be composed of a fine network of irregular anastomosing strands. This network closely resembled the previously characterized cord network of the basement membrane. The cords are known to be composed of a 1.5 to 3 nm thick core filament made up of type IV collagen which is surrounded by an irregular ‘sheath’ of other components. The strands in the subplasmalemmal network showed ultrastructural features similar to those of the cord network. Ribbon-like, 4.5 nm wide heparan sulfate proteoglycan ‘double tracks’ were previously reported to be associated with the cord network. Structures similar in size and appearance to the double tracks were also found in the subplasmalemmal network. At the cell-basement membrane border, the lamina densa of the basement membrane was in contact with the cell without the intervening space of a lamina lucida which was recently found to be an artefact caused by conventional tissue processing. Furthermore, the subplasmalemmal network appeared to be continuous through the plasma membrane, with the cord network of the basement membrane.(ABSTRACT TRUNCATED AT 250 WORDS)

Does the introduction of a new player, the endoplasmic reticulum, create more or less confusion in understanding the mechanism(s) of pigmentary organelle translocations?

In 1925, Wilson listed, in his classic third edition of Cell in Development and Heredity, four theories for the morphological and physiological characteristics of cytoplasm; each theory provided some sort of explanation as to the mechanism(s) of organelle translocations. During the past twenty years, cell biologists have focused their attentions on the cell's cytoskeleton, microtrabecular lattice, and associated mechanochemical motors which drive organelles along cytoskeletal tracks. A number of cell types have been used to study organelle translocations, but chromatophores, pigment cells, from cold-blooded vertebrates have been one of the more popular models. This article reviews some of the research findings during the past twenty years, particularly those involving cytoplasmic elements: i.e, microfilaments, intermediate filaments, microtubules, and mechanochemical motors. In addition, it contrasts the proposed involvement of these elements in organelle translocations with the endoplasmic reticulum, a tubulovesicular organelle, which we recently demonstrated is responsible, through its elongation or retraction, for the translocations of carotenoid droplets in goldfish xanthophores and swordtail fish erythrophores. Here, the carotenoid droplets are not free in the cytoplasm and do not translocate via cytoskeletal tracks, but instead are attached to or are a part of the endoplasmic reticulum. On the other hand, carotenoid droplets of squirrel fish erythrophores are free in the cytoplasm and appear to translocate via microtubules. Finally, the rates of pigmentary organelle translocations are reviewed in light of the participation of the cytoskeletal elements with the endoplasmic reticulum.

Cryo-electron microscopy of nervous tissue. A review

The present work attempts to demonstrate that cryofixation is a valuable method for the study of the nervous tissue. The use of the newly developed methods of cryofixation and freeze-etching without fixatives or cryoprotectants allows new exciting perspectives for the electron microscopical observation of cellular components, emphasizing their three-dimensional morphological structures. Significant contributions have been made on the fine structure of the cytoskeleton, cell membranes and cell organelles. The components of the cytoskeleton are distributed in different composition through the perikarya, dendrites and axon. The ubiquitous presence of the cytoskeleton suggests a crucial role in the functional activities of the neurons, especially in relation to the intracellular communication and to developmental and regeneration processes. Vitrified cellular membranes of myelin sheaths and rod outer segments have been observed in hydrated state by using cryofixation and cryotransfer techniques. These procedures allow new insights into the supramolecular structure and an approximation of morphological data to the present biophysical membrane model including a critical comparison with the current descriptions gained by conventional electron microscopy.

Mitochondria covered with a net of parallel and latticed filaments in nigral neurons of monkeys with experimental parkinsonism

Nigral neurons of crab-eating monkeys treated with 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) showed a peculiar configuration occasionally in mitochondria. The outer membrane of mitochondria was covered with a net of fine parallel or latticed filaments, which turned spirally about the long axis of the mitochondria. The filaments were approximately 8 nm in diameter: parallel filaments were arranged at intervals of about 13 nm from center to center; and latticed filaments intersected each other at an angle of almost 135 degrees. When mitochondria were present in groups, the intermitochondrial gap was occasionally filled with the same parallel filaments. The netted mitochondria were frequently associated with intramitochondrial abnormalities such as small floculent inclusions and disintegrated cristae. Only one or two netted mitochondria were counted in the perikaryon of one section of an injured neuron. They appeared in about one-third of mildly or moderately injured neurons in three of six MPTP-treated monkeys, and not in normal surviving and recovering neurons of treated animals, or in neurons of control animals. We consider the netted mitochondria to be a pathological configuration related to a metabolite of oxidation of MPTP, and to be different from the stubby mitochondria reported in amyotrophic lateral sclerosis (ALS) and a non-ALS case.

Effect of sodium butyrate on actin distribution in rat 3Y1 fibroblasts in monolayer culture

We studied the effect of sodium butyrate, a potent G1/G2-arresting agent, on actin distribution in rat 3Y1 fibroblasts in monolayer culture by fluorescence microscopy of cells stained with 7-nitrobenz-2-oxa-1, 3-diazole phallacidine (NBD-Ph). When randomly proliferating cells were arrested mainly in G1 phase with butyrate, a reversible overaccumulation of cellular net protein occurred. In the G1-arrested cells, actin markedly accumulated at the margin of cells, and a network structure of actin stress fibers appeared. When density-arrested cells were replated sparsely and rearrested in the G1, early S, and G2 phases with butyrate or hydroxyurea, the actin network was observed extensively in the cells arrested in the G1 and G2 phases with butyrate. These results agree with our previous results indicating the existence of some physiological similarity between cells in the G1 and G2 phases and suggest that actin distribution somehow depends on the phases of the cell cycle. The actin profiles observed by the NBD-Ph staining were confirmed by transmission electronmicroscopy (TEM) of negatively stained whole cells. TEM further revealed that electron-dense amorphous materials were present at crossing points in the network but rarely present on interconnecting microfilament bundles.

The cytoplasmic matrix: its volume and surface area and the diffusion of molecules through it

In this work we look into the problem of why proteins, unlike small molecules, diffuse in the cytoplasm much more slowly than in aqueous solutions. In order to examine whether the cytoplasmic matrix could, by simple obstruction, retard protein diffusion to such an extent, we developed a method to measure semiquantitatively the fractional volume occupied by the cytoplasmic matrix (which includes the microfilaments, intermediate filaments, microtubules, and the microtrabeculae of the cytoplasmic matrix). This method yielded values in the range of only 16-21%. Thus, a more elaborate model is suggested in which the diffusing proteins bind and dissociate constantly from the surfaces in the cytoplasmic matrix. From this model, the diffusion coefficients and the measured values of the fractional volumes, we calculated the corresponding binding constants. These values indicate that most of the diffusing proteins are bound to the matrix at any given time, in spite of the possibility that they may bind and dissociate very rapidly. In addition, from our measurements, we estimate the surface area of structures within the cytoplasmic matrix to be in the range of 69,000-91,000 micron 2 per cell.

Effects of folic acid upon filopodia of Dictyostelium discoideum vegetative amoebae

Living vegetative D, discoideum amoebae were studied to determine whether their filopodia respond to folic acid, a chemoattractant for these cells. Exponentially growing amoebae (ca. 10 micron diameter) exhibit 5-30 micron long filopodia; at stationary phase, aggregation competent amoebae have numerous multibranched filopodia up to 100 micron long. Folic acid was observed to stimulate production, elongation, and branching of filopodia with its effects progressively changing as the amoebae approach aggregation. Filopodial construction was also found to be dependent upon Mg2+ levels. The significance of these results is discussed with respect to progressive changes within the vegetative phase as well as to the mechanisms of amoeboid movement, pseudopodial activity, and chemotaxis.

Altered distribution profiles of endoplasmic reticulum subfractions after incubation of Krebs II ascites cells with different concentrations of cytochalasin B

Information on the interaction between endoplasmic reticulum (ER) membranes and components of the skeletal network of the cell was gained by treating cells with the antimicrofilament agent cytochalasin B prior to cell disruption by nitrogen cavitation. Treatment of Krebs II ascites cells with cytochalasin B (5-10 micrograms ml-1) resulted in an increased yield of three ER membrane subfractions--heavy rough (HR), light rough (LR) and smooth (S) membranes, as judged by 3H-choline incorporation in gradient fractions following discontinuous sucrose gradient centrifugation. The major increase was observed in the HR fraction. These results indicate that the actual yield of the respective ER membrane subfractions after cell disruption is dependent on the degree of direct and/or indirect interaction between individual ER membranes and actin containing filaments of the cytoskeleton in the intact cell.

A simple technique for the visualization of whole mount cytoskeletons with transmission electron microscopy

Examination of whole mount cells in the transmission electron microscope has been useful in studies of cellular architecture. The common technique is to grow cells directly on formvar-coated, gold grids for direct observation through a cell. We report a technique for obtaining whole mount preparations which requires neither fragile formvar films nor expensive, gold grids. Cells are grown on palladium-coated coverslips and processed for electron microscopy. The cells and the palladium substrate are separated from the coverslip. The cell-palladium complex is then picked up on copper grids as in thin section processing. We compare images of the cytoskeleton using our technique with images using previously described techniques and present preliminary observations of contracting cell models. Such contractions would tear formvar films if attempted on cells grown in the conventional manner for whole mount examination. Our technique allows cells to contract without tearing the underlying substrate.

Firm structural associations between migratory pigment granules and microtubules in crayfish retinula cells

The morphology of associations between mobile pigment granules and microtubules of the crayfish retinula cells was examined with transmission electron microscopy. Many pigment granules were found associated with microtubules through linkages of fuzzy appearance in thin sections. The linkages were revealed as discrete strands of variable shape in rotary-shadowed replicas of freeze-fractured and deep-etched specimens. The only feature of constant morphology among these connections consisted of 2-4-nm filaments projecting laterally from the microtubules. The firmness of the pigment granule-microtubule associations was judged by their ability to hold up during cell disruption procedures of increasing disaggregation effects in a low-Ca++ stabilization buffer. The results of these tests were inspected with scanning electron microscopy and with transmission electron microscopy of negatively stained preparations. Numerous pigment granules remained associated with a stable microtubule framework after the plasma membrane had been stripped away. Moreover, granule-microtubule attachments survived breakdown of this framework into free fascicles of microtubules. The pigment granules were associated with the free microtubules either individually or as clusters entangled in a fibrous material interwoven with 10-nm filaments. These findings attest that many pigment granules are bound to microtubules through linkages that constitute effective attachments. Further, it is demonstrated that a highly cohesive substance associates the pigment granules with one another. These conclusions are discussed in terms of a pigment transport mechanism in which a network of interconnected granules would establish firm transient interactions with a supporting skeleton of microtubules.

Mitotic architecture of the cell: the filament networks of the nucleus and cytoplasm

The skeletal framework of cells at the various stages of mitosis are prepared by extraction with nonionic detergent and examined by stereoscopic whole mount electron microscopy. The insoluble filament network remaining after the detergent-extraction and the depolymerization of microtubules is shown. The nonchromatin filament network of the nucleus, or nuclear matrix, becomes visible as the chromatin condenses at prophase. Filaments are associated with the chromosomes throughout mitosis. Parts of the chromosomes are associated with or are near the nuclear lamina at early stages. The nuclear lamina disappears at metaphase while chromosomes remain associated with filaments now continuous with the cytoplasmic network. Microtubules appear to be unnecessary for maintaining the chromosome position in these preparations since comparison of cells with and without microtubules shows no gross change in chromosome arrangement. The cellular filament network at metaphase and anaphase appears continuous from the plasma lamina to the chromosomes. The filament networks visualized here may be responsible for the prometaphase chromosome movement and participate in the formation of the midbody.

A method for studying the three-dimensional organization of cytoskeletal elements of cells: improvements in the polyethylene glycol technique

A method utilizing polyethylene glycol (PEG) as an extractable embedment for electron microscopy is described. Tissues are fixed according to conventional protocols, embedded in PEG, and sectioned. Sections (ranging from 100 to 500 nm in thickness) are mounted on grids, divested of their PEG matrix, critical-point-dried, and examined stereoscopically. This method greatly facilitates studies on the three-dimensional organization of cytoskeletal and cytoplasmic contractile systems in both muscle and nonmuscle cells.

Distinctive subcellular alterations induced by hypertonic stress in sea urchin eggs

Sea urchin eggs continuously exposed to a hypertonic solution were ultrastructurally examined for osmotic-stress induced alterations. No fertilization membranes formed during the treatment and the surface-cortex complexes remained unaltered from the unfertilized state. However, the osmotic stress did induce a number of subcellular changes. During the first 30 minutes of the treatment the eggs formed many endoplasmic reticulum whorls and compacted Golgi body aggregations. Both of these new formations can be correlated with rapid changes in intracellular calcium, known to occur in hypertonic stressed eggs. Aggregations of mitochondria could be observed at later stages; these aggregations can also be related to subcellular stress and possible changes in internal calcium concentrations. The various morphological transitions within the cytoplasm, along with the lack of a cortical reaction in these eggs, not only supports the idea that calcium is released during parthenogenetic activation, but also suggests that this free calcium originates from stores other than the stores that are involved during fertilization or simple artificial activation.

Observations on the role of smooth endoplasmic reticulumin glucocorticoid-induced hepatic glycogen deposition

We have studied by quantitative electron microscopy the relationship of specific hepatic cellular organelles to glycogen synthesis using dexamethasone, a potent synthetic glucocorticoid, to induce glycogen deposition in livers of adrenalectomized rats. Chemical and ultrastructural glycogen determinations revealed that the livers of fasted adrenalectomized rats had very low glycogen levels. Dexamethasone caused a time-related increase in hepatic glycogen which was the result of increases in the number of hepatocytes depositing glycogen and the amount of glycogen in each cell. The surface density of smooth endoplasmic reticulum (SER) in centrilobular and periportal hepatocytes also increased after treatment with dexamethasone; this increase preceded glycogen deposition. The newly deposited glycogen was spatially associated with membranes of SER, and a continued increase in SER surface density was correlated temporally with the increasing glycogen volume density. In both centrilobular and periportal hepatocytes, the surface density of rough endoplasmic reticulum (RER) initially decreased after dexamethasone administration but later increased. These data support the hypothesis that dexamethasone-induced enhancement of SER is functionally associated with the increase in glycogen, and that although the initial increase in SER may occur through transformation of RER to SER, later increases in SER require synthesis of new membranes.

Putative association of mitochondria with a subpopulation of intermediate-sized filaments in cultured human skin fibroblasts

Cultured cell Triton cytoskeletons enriched in intermediate filaments by extraction in high and low salt show, in addition to known intermediate-filament proteins and actin, a few other tenaciously bound polypeptides. An antibody raised against one of these polypeptides (IEF 24) is shown to react specifically with mitochondria of different cell types. With methanol-acetone fixation, required for the antibody reaction, the characteristically long mitochondria of human skin fibroblasts fragment into strings of beads, as identified by antibody staining in the light microscope and whole-mount electron microscopy. From the colinear organization of these beads, their codistribution with the intermediate-filament network and their retention in salt-extracted cytoskeletons, it is suggested that a subpopulation of the intermediate filaments can serve as an anchorage site for mitochondria.

Cytostructural dynamics of spreading and translocating cells

Cytostructural changes during fibroblast spreading and translocation and during the transition between the two states have been studied in living cells and in the same cells after fixation and immunofluorescent staining. In time-lapse sequences we observe that birefringent arcs, sometimes circles, concentric with the cell perimeter, form near the periphery of a spreading cell, or that arcs form near the leading edge of a locomoting cell. The arcs move toward the nucleus, where they disappear. In spreading cells, radial stress fibers extend from the region of the cell nucleus to the periphery. The arcs or circles and the stress fibers are visualized in the same cells after fixation and staining with fluorescein-conjugated antiactin antibodies. Stained images of spreading cells show the arcs and stress fibers in the same plane of focus. At points of intersection with arcs, stress fibers are bent toward the substrate on which the cell is moving. During a transitional stage between spreading and translocation the cytostructure undergoes reproducible changes. Arcs and circle cease to form. The radial stress fibers elongate, spiral around the nucleus, and move to the periphery as a band of filaments. We interpret the moving arcs as condensations of a microfilament network that move toward the nucleus as compression waves. As elements of the net are brought close together by the compression wave, contraction may occur and facilitate the condensations.

The cytoskeleton of human polymorphonuclear leukocytes: phagocytosis and degranulation

Current evidence indicates that polymorphonuclear leukocyte (PMN) chemotaxis and phagocytosis are effected by an actin-myosin contractile system. However, the structural relationship of the contractile cytoskeleton to cell motility is still in question. In addition, while evidence suggests that microtubules are responsible for orientation during chemotaxis, the role of microtubules in degranulation is unresolved. To determine the organizational relationship between these cytoskeletal elements and phagocytosis, we examined whole-mount preparations of PMNs engulfing bacteria. These preparations were examined in the transmission electron microscope (EM) and photographed as stereo pairs. Two important observations were made. First, there was an increased density of cytoskeletal elements in the pseudopod surrounding bacteria. Second, microtubule elements were intimately associated with lysosomal granules, vesicles, and phagosomes. Lysosomal granules and vesicles aligned along microtubules and clustered around phagosomes. This suggests that the microtubules may provide a tracking mechanism whereby lysosomes are specifically parceled out to phagocytic vacuoles. These results also suggest that phagocytosis and degranulation may involve different effector mechanisms.

The cytoplast: a unit structure in chromatophores

We followed the translocation of identifiable pigment granules in living erythrophores through normal aggregation and dispersion and observed that they always return in dispersion to the same location relative to the whole pigment complex. This is interpreted to mean that each granule occupies a fixed position within a unit structure, the cytoplast. This position is retained even though the cytoplast undergoes dramatic reversals in form from ellipsoid to spheroid and back again with each aggregation and dispersion. The major structural components of the cytoplast, besides pigment granules, are microtubules and microtrabeculae. The latter constitute an irregular lattice that is confluent with microtubules and contains the pigment granules. In aggregation, the microtrabeculae shorten and seemingly contribute to the contraction of the entire cytoplast plus pigment. In dispersion, the microtrabeculae elongate in an apparent restructuring of the ellipsoidal cytoplast. The microtubules, however, persist in the cell cortex and appear to give radial direction to the pigment motion.

A new suggestion of the design of rational anticancer therapy: experimental studies in mice

In attempts to develop a rational anticancer strategy the same homologous tissue in 3 conditions were used side by side as targets: normal epidermis of the mouse back. Tween 60R-provoked benign epidermal hyperplasia, and carcinogen-provoked malignant condition. In contrast to the highest tolerated doses of the cytostatics conventionally used, the dose was stepwise decreased towards the subthreshold level. Then the smallest dose that caused the slightest detectable injury to the malignant cells was employed. The results show that the dose of the cytostatics (colchicine, and vinblastine sulfate) can be reduced to 1/12 if the drug is linked to dimethyl-sulfoxide (DMSO), a compound with unique hydrating and oxido-reducing properties. The cytostatic-DMSO complex acts selectively, sparing the viability of the normal and hyperplastic cells, but at the same time increasing the vulnerability of the malignant cells. The specific target for cytostatic-DMSO complex is the 3-dimensional cytoskeleton (the differentiation organelle) which is deranged in malignant cells. The measure causes a morbid swelling (20-fold, or more) of the cytoplasm which leads to collapse of the cytoskeleton, so that the marginal quantities of the cytostatics can exert their effects in the highly re-hydrated water matrix of the malignant cells. It is, moreover, probable that the doses of the cytostatic in DMSO could be further reduced to 1/100, or even to 1/1,000. The polarization microscopic technique reveals events down to the (sub)-molecular level. The cytological material comprises 930,000 karyokinetic assemblies and 14,522,600 corresponding nucleated non-dividing cells in various cutaneous conditions of 1,860 mice. The conclusions were drawn only when the differences between corresponding parameter pairs were statistically highly significant (P less than 0.001).

High voltage electron microscopy studies of axoplasmic transport in neurons: a possible regulatory role for divalent cations

Light and high voltage electron microscopy (HVEM) procedures have been employed to examine the processes regulating saltatory motion in neurons. Light microscope studies demonstrate that organelle transport occurs by rapid bidirectional saltations along linear pathways in cultured neuroblastoma cells. HVEM stereo images of axons reveal that microtubules (Mts) and organelles are suspended in a continuous latticework of fine microtrabecular filaments and that the Mts and lattice constitute a basic cytoskeletal structure mediating the motion of particles along axons. We propose that particle transport depends on dynamic properties of nonstatic microtrabecular lattice components. EXperiments were initiated to determine the effects of changes in divalent cation concentrations (Ca2+ and Mg2+) on: (a)the continuation of transport and (b) the corresponding structural properties of the microtrabecular lattice. We discovered that transport continues or is stimulated to a limited extent in cells exposed to small amounts of exogenously supplied Ca2+ and Mg2+ ions (less than 0.1 mM). Exposure of neurons to increased dosages of Ca2+ and Mg2+ (0.2-1.0 mM) stimulates transport for 2-4 min at 37 degrees C, but after a 5- to 20-min exposure the saltatory movements of organelles are observed gradually to become shorter in duration and rate particle motion ceases to occur. HVEM observations demonstrated that Ca2+ - and with the cessation of motion. Ca2+-containing solutions produced contractions of the microtrabecular filaments, whereas Mg2+-containing solutions had the opposing effect of stimulating an elongation and assembly (expansion) of microtrabeculae. On the basis of these observations we hypothesize that cycles of Ca2+/Mg2+-coupled contractions and expansions of the microtrabecular lattice probably regulate organelle motion in nerve cells.

Epithelial cell motility: the effect of 2-deoxyglucose on cell migration, ATP production, and the structure of the cytoplasmic ground substance in lamellipodia of epithelial cells in culture

Using a line of epithelial cells (SCCA5) derived from a spontaneous rat carcinoma, the glucose analogue 2-deoxyglucose (2DG) has been shown by time-lapse cinemicrography to produce a cessation of motility by 1 hour that can be reversed by replacement of the 2DG, and does not occur in equivalent media with or without glucose or in 2DG-containing media with added pyruvate and citrate. The effect on the cells at the edge of an epithelial island is to prevent the formation of new lamellipodia and produce a progressive retraction and condensation of lamellipodia already present. This effect of 2DG on motility corresponds with a significant reduction in the level of ATP that is partially restored after 30 minutes in the recovery incubation. Only a slight reduction in protein synthesis occurs in the presence of 2DG. The external morphology and the cytoplasmic ground substance of the cells were studied by scanning electron microscopy and high voltage electron microscopy respectively. It was found that after incubation in 2DG for 1 hour the outline of the free edges of the cells was distorted resulting in redistribution of microvilli, condensation of cytoplasm into strands, and irregular projections from the edges of residual lamellipodia. The structure of the cytoplasmic ground substance in lamellipodia from cells incubated in 2DG for 3 hours was distinctly different from that in cells incubated for 3 hours in 2DG then recovered for 25 minutes, or in cells incubated in glucose-containing medium for 3 hours. In the 2DG-treated cells the lattice-like structure evident in critical-point-dried cells was condensed into short thick strands that terminated in bulbous ends, whereas in cells recovered for 25 minutes the lattice material was elongated and tapering and the interlattice space relatively expanded. The results obtained support the concept of modulation occurring in the structure of the microtrabecular lattice component of the cytoplasmic ground substance coincident with alterations in cell function and metabolic state.

Organization of actin in the leading edge of cultured cells: influence of osmium tetroxide and dehydration on the ultrastructure of actin meshworks

The ordered structure of the leading edge (lamellipodium) of cultured fibroblasts is readily revealed in cells extracted briefly in Triton X-100-glutaraldehyde mixtures, fixed further in glutaraldehyde, and then negatively stained for electron microscopy. By this procedure, the leading edge regions show a highly organised, three-dimensional network of actin filaments together with variable numbers of radiating actin filament bundles or microspikes. The use of Phalloidin after glutaraldehyde fixation resulted in a marginal improvement in filament order. Processing of the cytoskeletons though the additional steps generally employed for conventional electron microscopy resulted in a marked deterioration or complete disruption of the order of the actin filament networks. In contrast, the actin filaments of the stress fiber bundles were essentially unaffected. Thus, postfixation in osmium tetroxide (1% for 7 min at room temperature) transformed the networks to a reticulum of kinked fibers, resembling those produced by the exposure of muscle F-actin to OsO4 in vitro (P. Maupin-Szamier and T. D. Pollard. 1978. J. Cell Biol. 77:837--852). While limited exposure to OsO4 (0.2+ for 20 min at 0 degrees C) obviated this destruction, dehydration in acetone or ethanol, with or without post-osmication, caused a further and unavoidable disordering and aggregation of the meshwork filaments. The meshwork regions of the leading edge then showed a striking resemblance to the networks hitherto described in critical point-dried preparations of cultured cells. I conclude that much of the "microtrabecular lattice" described by Wolosewick and Porter (1979. J. Cell Biol. 82:114--139) in the latter preparations constitutes actin meshworks and actin filament arrays, with their associated components, that have been distorted and aggregated by the preparative procedures employed.

A simple method for whole-cell preparation in electron microscopy

A simple method for whole-cell preparation without using gold or platinum grids as substrata for culture is described. Cells were cultured on formvar film over round pores, each 3 mm in diameter, of Thermonox coverslips. The cells on the formvar coated coverslip are fixed, stained, dehydrated in situ, and introduced into a critical point drying apparatus. A small quantity of 0.2% mesh-cement is applied to slot grids, and they are laid onto the formvar film over the pores of the coverslip. After the grids are removed from the plastic substratum, they are ready for observation under the electron microscope.

Structural interaction of cytoskeletal components

Three-dimensional cytoskeletal organization of detergent-treated epithelial African green monkey kidney cells (BSC-1) and chick embryo fibroblasts was studied in whole-mount preparations visualized in a high voltage electron microscope. Stereo images are generated at both low and high magnification to reveal both overall cytoskeletal morphology and details of the structural continuity of different filament types. By the use of an improved extraction procedure in combination with heavy meromyosin subfragment 1 decoration of actin filaments, several new features of filament organization are revealed that suggest that the cytoskeleton is a highly interconnected structural unit. In addition to actin filaments, intermediate filaments, and microtubules, a new class of filaments of 2- to 3-nm diameter and 30- to 300-nm length that do not bind heavy merymyosin is demonstrated. They form end-to-side contacts with other cytoskeletal filaments, thereby acting as linkers between various fibers, both like (e.g., actin- actin) and unlike (e.g., actin-intermediate filament, intermediate filament-microtubule). Their nature is unknown. In addition to 2- to 3-nm filaments, actin filaments are demonstrated to form end-to-side contacts with other filaments. Y-shaped actin filament "branches" are observed both in the cell periphery close to ruffles and in more central cell areas also populated by abundant intermediate filaments and microtubules. Arrowhead complexes formed by subfragment 1 decoration of actin filaments point towards the contact site. Actin filaments also form end-to-side contacts with microtubules and intermediate filaments. Careful inspection of numerous actin-microtubule contacts shows that microtubules frequently change their course at sites of contact. A variety of experimentally induced modifications of the frequency of actin-microtubule contacts can be shown to influence the course of microtubules. We conclude that bends in microtubules are imposed by structural interactions with other cytoskeletal elements. A structural and biochemical comparison of whole cells and cytoskeletons demonstrates that the former show a more inticate three-dimensional network and a more complex biochemical composition than the latter. An analysis of the time course of detergent extraction strongly suggests that the cytoskeleton forms a structural backbone with which a large number of proteins of the cytoplasmic ground substance associate in an ordered fashion to form the characteristic image of the "microtrabecular network" (J.J. Wolosewick and K.R. Porter. 1979. J. Cell Biol. 82: 114-139).

Microfilament reorganization in normal and cytochalasin B treated adherent thrombocytes

Thrombocyte adhesion following activation by a Formvar surface involves a morphologic transition resulting in a fully spread cell. Correlative SEM and whole mount TEM were used to study the cytoskeletal alterations that accompany changes in surface morphology during adhesion. Following initial adhesion, thrombocytes extend slender pseudopods containing longitudinally oriented bundles of filaments that are 13-22 nm in diameter. Concomitant with pseudopod extension, a cytoplasmic hyalomere, consisting of a dense filamentous network, extends between the pseudopods and ultimately results in a fully spread cell. Treatment of thrombocytes with cytochalasin B (10(-5) M) caused clumping of the hyalomere filament network and retraction of the hyalomere. Examination of partially retracted cells revealed that pseudopod filament bundles were continuous with the contracting filamentous network. It is concluded that pseudopod filament bundles and cytoplasmic hyalomere filaments are interconvertible and that their organizational relationship changes in accordance with gross morphologic changes.

The control of pigment migration in isolated erythrophores of Holocentrus ascensionis (Osbeck). I. Energy requirements

Erythrophores isolated from the scales of the marine teleost, Holocentrus ascensionis (Osbeck), are capable of rapidly aggregating or dispersing numberous red pigment granules within their cytoplasm by translocating them along radial paths delineated by bundles of radially oriented microtubules. Pigment translocation is accompanied by transformations in the morphology of the cytoplasmic matrix, or microtrabecular lattice (MTL), in which the pigment granules are suspended. It appears that the MTL as a whole contracts toward the cell center during aggregation, carrying the pigment granules inward along with it, and is restructured during dispersion, using the radial microtubules as guides. We examined the energy requirements of pigment migration and the accompanying MTL transformations. Cellular ATP was depleted using the specific metabolic inhibitors 2,4 dinitrophenol, NaCN and oligomycin. All three of these drugs, which inhibit oxidative phosphorylation by different mechanisms, prevent both pigment dispersion and MTL transformation to dispersed morphology, while aggregation is unaffected. Inhibitor-treated cells recover normal pigment movements and MTL morphology when inhibitor is washed out of the cells with fresh medium. Potential energy apparently is stored in the MTL by some ATP-dependent process during dispersion and is converted to kinetic energy during aggregation. The results of this study strengthen the hypothesis that the MTL, working in concert with the radial microtubules, is the vehicle for pigment translocation in the erythrophore system.

Slow components of axonal transport: two cytoskeletal networks

We have identified two slowly moving groups of axonally transported proteins in guinea pig retinal ganglion cell axons (4). The slowest group of proteins, designated slow component a (SCa), has a transport rate of 0.25 mm/d and consists of tubulin and neurofilament protein. The other slowly transported group of proteins, designated slow components b (SCb), has a transport rate of 2-3 mm/d and consists of many polypeptides, one of which is actin (4). Our analyses of the transport kinetics of the individual polypeptides of SCa and SCb indicate that (a) the polypeptides of SCa are transported coherently in the optic axons, (b) the polypeptides of SCb are also transported coherently but completely separately from the SCa polypeptides, and (c) the polypeptides of SCa differ completely from those comprising SCb. We relate these results to our general hypothesis that slow axonal transport represents the movements of structural complexes of proteins. Furthermore, it is proposed that SCa corresponds to the microtubule-neurofilament network, and that SCb represents the transport of the microfilament network together with the proteins complexed with microfilaments.

The application of polyethylene glycol (PEG) to electron microscopy

The cytoplasm of cells from a variety of tissues has been viewed in sections (0.25-1 micrometers) devoid of any embedding resin. Glutaraldehyde- and osmium tetroxide-fixed tissues were infiltrated and embedded in a water-miscible wax, polyethylene glycol (PEG), and subsequently sectioned on dry glass or diamond knives. The PEG matrix was removed and the sections were placed on Formvarcarbon-polylysine-coated grids, dehydrated, dried by the critical-point method, and observed in either the high- or low-voltage electron microscope. Stereoscopic views of cells devoid of embedding resin present an image of cell utrastructure unobscured by electron-scattering resins similar to the image of whole, unembedded critical-point-dried or freeze-dried cultured cells observed by transmission electron microscopy. All organelles, including the cytoskeletal structures, are identified and appear not to have been damaged during processing, although membrane components appear somewhat less distinct. The absence of an embedding matrix eliminates the need for additional staining to increase contrast, unlike the situation with specimens embedded in standard electron-scattering resins. The PEG technique thus appears to be a valuable adjunct to conventional methods for ultrastructural analysis.

Filament organization revealed in platinum replicas of freeze-dried cytoskeletons

This report presents the appearance of rapidly frozen, freeze-dried cytoskeletons that have been rotary replicated with platinum and viewed in the transmission electron microscope. The resolution of this method is sufficient to visualize individual filaments in the cytoskeleton and to discriminate among actin, microtubules, and intermediate filaments solely by their surface substructure. This identification has been confirmed by specific decoration with antibodies and selective extraction of individual filament types, and correlated with light microscope immunocytochemistry and gel electrophoresis patterns. The freeze-drying preserves a remarkable degree of three-dimensionality in the organization of these cytoskeletons. They look strikingly similar to the meshwork of strands or "microtrabeculae" seen in the cytoplasm of whole cells by high voltage electron microscopy, in that the filaments form a lattice of the same configutation and with the same proportions of open area as the microtrabeculae seen in whole cells. The major differences between these two views of the structural elements of the cytoplasmic matrix can be attributed to the effects of aldehyde fixation and dehydration. Freeze-dried cytoskeletons thus provide an opportunity to study--at high resolution and in the absence of problems caused by chemical fixation--the detailed organization of filaments in different regions of the cytoplasm and at different stages of cell development. In this report the pattern of actin and intermediate filament organization in various regions of fully spread mouse fibroblasts is described.

Variation in cytoskeletal assembly during spreading of progressively subcultivated human embryo fibroblasts (IMR-90)

The cytoskeletons of early and late passage IMR-90 human diploid fibroblasts have been directly imaged in replicas of Triton X-100 extracted cells during spreading following reseeding. All cells from both young and sensescent cultures exhibit a cytoskeletal network of actin microfilaments, intermediate (10 nm) filaments, microtubules, and interconnecting thin filaments (6-8 nm in diameter) which do not interact with heavy meromyosin. Early passage cells assemble linear aggregates of actin filaments within 1 h of spreading. By 4 h of incubation, these bundles establish a structural bond with the cell membrane which results in resistance by the plasmalemma to detergent extraction at these sites. Furthermore, these membrane regions are associated with developing stress fibers of well-spread cells. In contrast, late passage cells exhibit slower spreading which correlates with a retarded assembly of actin bundles. In addition, by 8 h of spreading, cells of older cultures do not exhibit the regions of membrane-actin interaction which impart detergent resistance to the plasmalemma. We conclude that the ability to reassemble actin-actin and actin-membrane association during cell spreading is reduced with increased serial subcultivation of cells.

Electron microscopic visualization of the filamentous reticulum in whole cultured presumptive chick myoblasts

This present study describes an experimental approach whereby subcellular 3-dimensional filamentous structures present within whole cells can be examined, using a conventional transmission electron microscope. This procedure uses cells which have been cultured on carbon-coated titanium grids, and treated with Triton X-100 to extract the soluble cytoplasm. Subsequent fixation and critical-point drying allows filamentous proteins to be easily visualized, due to the increase in contrast produced by removal of the ground cytoplasm. The high resolution obtainable in these preparations permitted an initial classification and description of the filamentous reticulum within cultured presumptive myoblasts. This reticulum is a continuum of filaments and cables, all elements of which appear to be interconnected. These morphological findings were then correlated with the biochemical identification of detergent-insoluble proteins, of which only actin, myosin, and, perhaps, intermediate filament and LETS protein are the major elements.

Guinea-pig keratinocytes and melanocytes in tissue culture: scanning, transmission and high voltage electron microscope observations

Keratinocytes and melanocytes cultured from guinea-pig epidermis were studied with scanning, transmission and high voltage electron microscopy to characterize the surface and internal morphology. Keratinocytes exhibited contact-inhibition and a range of surface structures consistent with cell-cycle dependent changes. Stereoscopic analysis of high voltage electron micrographs indicated regular oval nuclei with nucleoli at different depths, while thin sections revealed local channels in the nuclei. Secondary cultures differed from primary cultures in the disorder of the microfilaments, in the failure to form desmosomes, and in the failure of melanocytes to persist in culture. The beaded surface of melanocytes was indicative of underlying melanosomes that were seen in high voltage micrographs. Melanocytes were rounded with moderate ruffles or were dendritic with ruffles on the termini. These findings are discussed in relation to the observational techniques and in relation to modes of locomotion of and pigment transfer to epidermal cells.