Lamellar Cytoplasm Research Articles

Unraveling the determinants of protrusion formation.

A computerized morphometric classification technique based on latent factors reveals major protrusion classes: factors 4, 5, and 7. Previous work showed that factor 4 represented filopodia, 5 the distribution of lamellar cytoplasm, and 7 a blunt protrusion. We explore the relationship of focal contact (FC) characteristics and their integrated actin cables to factors values. The results show that FC maturation/cytoskeletal integration affects factor 5, because FC elongation/integration was correlated with its values. On the contrary, 7 values decreased with maturation, so cable or FC size or their integration must be restricted to form these protrusions. Where integration did occur, the cables showed distinctive size and orientation, as indicated by correlation of 7 values with FC shape. Results obtained with myosin inhibitors support the interpretation that a central, isometric, contractile network puts constraints on both factor 5 and 7 protrusions. We conclude that cells establish functional domains by rearranging the cytoskeleton.

Expressions of Laminin-1 in Lung Alveolar Septa after CS gas Exposure in Rats

Background : Laminin-1 is known to have regular functions in the development and course of differentiation of the lungs. The morphogenesis and distribution of laminin-1 still remains as a mystery and its distribution and changes in the molecular structure of laminin-1 in the pathogenesis of the lung still is a subject of great controversy. In this study, experiments were done to delineate the distribution and changes in the amount of laminin-1 after inducing inflammation of the lungs by exposing experimental animals to CS gas and especially, to find compositions of laminin-1 within type II pneumocytes. Materials and Methods : The experimental subjects of study were newborn rats and the extracted tissue from the experimental rats were viewed under light microscope and electron microscope after the sections were treated with immunohistochemical methods and immunogold reaction methods using bounded gold particles. Results : 1) Lymphocytes and mononuclear phagocytes invaded the alveolar septa in the 2 day group rats after CS gas exposure and intense interstitial inflammation was seen in the 3 day group. 2) Laminin immunoreactions decreased to a moderate degree in the 2 and 3 day group rats after CS gas exposure and strong laminin immunoreactions were seen again in the 5 and 7 day group rats. 3) Gold particles in basal lamina of the lung blood-air barrier decreased and in the type I pneumocytes decreased in the 2 and 3 day group rats after CS gas exposure. 4) Gold particles were seen only on the surface of the cell membranes of type II pneumocytes of the 1 and 2 day group rats after CS gas exposure. 5) Few gold particles around the lamellar bodies and cytoplasm of type II pneumocytes in the control rat group and at 12 hours after CS gas exposure. Gold particles are seen only on the surface of type II pneumocytes of the 1 and 2 day group rats after CS gas exposure and are evenly distributed in small amounts in the cells of the 3 day group after CS gas exposure. Conclusion : CS gas exposure in the rats caused inflammation of lung alveolar septa and also induced a decrease in laminin-1 in basal lamina and loss of laminin-1 in the cytoplasm of type II pneumonocytes. As the inflammatory cells disappeared, an increase in the distribution of laminin-1 occurred. This reflects tissue regeneration functions of laminin-1 in the pneumocytes of rats and the distribution of laminin-1 in type II pneumocytes can be seen through the electron microscope using immunogold methods.

Mechanisms of polarization of the shape of fibroblasts and epitheliocytes: Separation of the roles of microtubules and Rho-dependent actin-myosin contractility.

Cultured fibroblasts possess a characteristic polarized phenotype manifested by an elongate cell body with an anterior lamella whose cell edge is divided into protrusion-forming and inactive zones. Disruption of the fibroblast microtubule cytoskeleton leads to an increase in Rho-dependent acto-myosin contractile activity and concomitant loss of structural polarity. The functional relationship of myosin-driven contractile activity to loss of fibroblast anterior-posterior polarity is unknown. To dissect the roles of microtubule assembly and of Rho-dependent contractility on structural polarization of cells, polarized fibroblasts and nonpolarized epitheliocytes were treated with the microtubule-depolymerizing drug, nocodazole, and/or the Rho kinase inhibitor, Y-27632. Fibroblasts incubated with Y-27632 increased their degree of polarization by developing a highly elongate cell body with multiple narrow processes extended from the edges of the cell. Treatment of fibroblasts with nocodazole, alone or in combination with Rho kinase inhibitor, produced discoid or polygonal cells having broad, flattened lamellae that did not form long lamellar extensions. Single cultured epitheliocytes of the IAR-2 line do not display anterior-posterior polarization. When treated with Y-27632, the cells acquired a polarized, elongate shape with narrow protrusions and wide lamellas. Nocodazole alone or in combination with Y-27632 did not change the discoid shape of epitheliocytes, however treatment with Y-27632 produced thinning of the lamellar cytoplasm. We conclude that microtubules provide the necessary framework for polarization of fibroblasts and epitheliocytes, whereas Rho-regulated contractility modulates the degree of polarization of fibroblasts and completely inhibits polarization in epitheliocytes.

Locomotory behaviour of epitheliocytes and fibroblasts on metallic grids.

Behaviour of epitheliocytes and fibroblasts on special discontinuous substrata (metallic grids with square openings of 45x45 microm2) was examined in order to compare the ability of these cells to spread in two mutually perpendicular directions and to stretch over the void spaces. Two cell types with typical fibroblastic morphology, the AGO 1523 line of human foreskin fibroblasts and secondary cultures of mouse embryo fibroblasts, and three cell types with typical epithelial morphology, primary mouse hepatocytes, the IAR-2 line of rat liver cells and the MDCK line of canine kidney epithelial cells (clone 20) were used. We also examined the epitheliocytes (MDCK cells, clone 20) transformed to fibroblast-like morphology by treatment with hepatocyte growth factor/scatter factor (HGF/SF). Time-lapse video microscopy, scanning electron microscopy and immunofluorescence microscopy were used to examine cell reorganizations at various stages of spreading. It was found that early stages of spreading of fibroblasts and epitheliocytes were similar: the cell spread along two bars, perpendicular to each other (bar and crossbar), with the formation of a small triangular lamellar cytoplasm stretched over the opening. Later central parts of the bodies of the fibroblasts retracted from the bars so that the cells remained attached only by their polar lamellae. Successive expansions and partial retractions of these lamellae led to elongation of the cell body crossing several openings of the grid. Epitheliocytes, in contrast to fibroblasts, at the late stages of spreading did not retract their bodies and did not contract polar lamellae. As a result, their central lamellae stretched progressively over the openings. As a result of the treatment of MDCK epitheliocytes with HGF/SF the behaviour of the cells on the grids became similar to that of fibroblasts. It is suggested that these distinct spreading patterns of epitheliocytes and fibroblasts are due to the type-specific differences in the actin-myosin cortex. Experiments with microtubule-specific drugs, colcemid and taxol, indicate that the organization of this cortex is under microtubular control.

Self-polarization and directional motility of cytoplasm

Background: Directional cell motility implies the presence of a steering mechanism and a functional asymmetry between the front and rear of the cell. How this functional asymmetry arises and is maintained during cell locomotion is, however, unclear. Lamellar fragments of fish epidermal keratocytes, which lack nuclei, microtubules and most organelles, present a simplified, perhaps minimal, system for analyzing this problem because they consist of little other than the motile machinery enclosed by a membrane and yet can move with remarkable speed and persistence.Results: We have produced two types of cellular fragments: discoid stationary fragments and polarized fragments undergoing locomotion. The organization and dynamics of the actin–myosin II system were isotropic in stationary fragments and anisotropic in the moving fragments. To investigate whether the creation of asymmetry could result in locomotion, a transient mechanical stimulus was applied to stationary fragments. The stimulus induced localized contraction and the formation of an actin–myosin II bundle at one edge of the fragment. Remarkably, stimulated fragments started to undergo locomotion and the locomotion and associated anisotropic organization of the actin–myosin II system were sustained after withdrawal of the stimulus.Conclusions: We propose a model in which lamellar cytoplasm is considered a dynamically bistable system capable of existing in a non-polarized or polarized state and interconvertible by mechanical stimulus. The model explains how the anisotropic organization of the lamellum is maintained in the process of locomotion. Polarized locomotion is sustained through a positive-feedback loop intrinsic to the actin–myosin II machinery: anisotropic organization of the machinery drives translocation, which then reinforces the asymmetry of the machinery, favoring further translocation.

Ultrastructural localization of calcium in mechanoreceptors of the oral mucosa.

Cytochemical localization of Ca2+ in Meissner corpuscles and Merkel cell-neurite complexes in the palatine mucosa of the Mongolian gerbil was studied by a combined oxalate antimonate-microwave irradiation procedure. The reaction products obtained were identified as calcium antimonate by EGTA solubility and X-ray microanalysis. Meissner corpuscles in the normal palatine rugae could be roughly classified into three types by amount and localization of Ca2+. Type I corpuscles were characterized by a high Ca2+ content in both the terminal axoplasm and caveolae of the lamellar plates, type II, by a low Ca2+ content in the terminal axoplasm and a high Ca2+ content in the lamellar cytoplasm. Type III corpuscles showed intermediate characteristics. Palatine rugae stimulated mechanically during fixation contained an increased number of type I corpuscles. On the other hand, two patterns were distinguished in the distribution of Ca2+ in Merkel cells in palatine rugae fixed under normal conditions. One showed abundant Ca2+ dispersed throughout the cell, while in the other, Ca2+ was specifically localized in the Golgi apparatus and mitochondria. Similar distribution patterns also were observed in palatine rugae that had received mechanical stimulus during fixation. Axon terminals of most Merkel cell-neurite complexes in normal palatine rugae were poor in axoplasmic Ca2+, whereas those in most Merkel cell-neurite complexes in mechanically stimulated palatine rugae contained abundant Ca2+ in their axoplasm.

Measuring elastic properties of cells by evaluation of scanning acoustic microscopy V( Z) values using simplex algorithm

In this paper a new technique is proposed to determine the acoustic properties as well as the thickness (and volume) of biological cells. Variations of thickness, density, acoustic wave velocity, stiffness, and attenuation coefficient of a living or dead cell are obtained by scanning the cell by an acoustic microscope. The distance between the cell and the microscope lens is varied and several voltage curves are thus obtained. These curves are then inverted by simplex optimization technique to obtain the cell parameters. The spatial resolution of the method is limited to the resolution of the scanning acoustic microscope. It allows to take advantage of the full range of frequencies and amplification of the microscope. Characteristic distributions of stiffness are exemplified with an endothelial cell in culture. The main part of the thin, lamellar cytoplasm has high stiffness, which drops close to the lamella/cell body transition region and only slightly increases again through the central part of the cell. Acoustic attenuation seems to be related to two factors, cytoplasm accumulation (in the lamellar parts) and scattering in the central part rich in organelles.

Polarization of cytoplasmic fragments microsurgically detached from mouse fibroblasts

We have studied the polarity of cytoplasm organization in tiny fragments of mouse embryo fibroblasts, produced by the microsurgical separation of long processes of cytochalasin-treated cells. In the cytochalasin-free medium fragments re-spreaded and developed small lamellas at one or both of their ends. Granules, visible at phase-contrast optics, were always collected in the central part of the fragment. Lamellas of the fragment, as well as lamellar cytoplasm of parent cells, were able to clear surface receptors patched by concanavalin A and an antibody to concanavalin A. Immunofluorescence microscopy showed that the fragments always contained actin microfilament bundles parallel to the long axis of the fragment, but microtubules were present not more than for 6 hrs after detachment of the fragments from the cell bodies. Fragments detached from the cells treated with colcemid and cytochalasin simultaneously and transferred into the drug-free medium never had any microtubules. In spite of that, their behaviour was similar to the behaviour of the fragments that were produced from the control cells treated only with cytochalasin. These results show that the small fragments of mouse embryo fibroblasts are able to maintain the polar organization of cytoplasm and the microtubules are not responsible for this organization.

Direct evidence for microfilament-mediated capping of surface receptors on crawling fibroblasts.

On moving fibroblasts, cell-surface receptors cross-linked by antibodies or lectins are cleared centripetally from regions of lamellar cytoplasm and collect as a cap over the perinuclear region. Current theories of the mechanism of receptor redistribution on cultured cells variously implicate membrane flow, lipid flow, surface waves and linkage to the cytoskeleton. The last, the anchorage model, is based on observations that ligand-induced clusters of receptors on a variety of cell types either attach to actin or align over structures containing actin, myosin and alpha-actinin. I show here that the capping of antibody receptors on crawling chick embryo fibroblasts is highly coordinated with the apparent centripetal movements of arcs, which are part of a dorsal cortical actin-microfilament sheath (DCMS). This phenomenon can be directly observed in living cells. The data support the anchorage model of membrane receptor mobility and suggest that there is a continuous flow of actin associated with fibroblast locomotion.

Spreading of fibroblasts in medium containing cytochalasin B: formation of lamellar cytoplasm as a combination of several functional different processes.

Normal cultured mouse fibroblasts spreading on solid substrate extend and attach numerous pseudopods; lamellar cytoplasm is eventually formed from the attached pseudopods. Fibroblasts spreading in the presence of cytochasin B (CB) from de novo a system of arbor-like branched processes rather than lamellar cytoplasm. The growing and fully formed arbor-like processes, in contrast to normal lamellar cytoplasm, have low contractility and are unable to clear patched concanavalin A receptors from their surfaces; their attachement sites are not associated with microfilament bundles. The cells spreading in medium containing CB and Colcemid do not form well-organized branched structures but extend and attach numerous unstable pseudopods. It is suggested that normal formation of lamellar cytoplasm can be regarded as a combination of several functionally different processes: (a) of rudimentary pseudopodial reactions resistant to CB and Colcemid; (b) of CB-sensitive lamellization; and (c) of Colcemid-sensitive stabilization.

Inhibition of cell spreading by lysosomotropic amines

Ammonia and various amines with weak-base properties have been shown to accumulate in acidic cellular vacuoles such as lysosomes, and to inhibit lysosomal degradative processes in several types of cells in vitro [l-l I]. In addition these compounds may: inhibit protein secretion [ 121 as well as other vesicle-mediated secretory processes [ 131, inhibit the adsorbtive uptake of macromolecules [ 14161, suppress the activity of certain receptor-dependent toxins [ 17,181, and prevent the focal patching of occupied cell-surface receptors normally preceding internalization and degradation of receptor-ligand complexes [ 191. That all of these effects are observed only at relatively high amine concentrations (2-10 mM) may indicate that they are consequential of a generalized perturbation of cellular membrane mobility, caused by the accumulation of amines in certain compartments of the cellular membrane system. Isolated rat hepatocytes have been shown to attach to and spread readily on substrata of adsorbed serum (fibronectin) or collagen [20-221, and scanning electron microscopy has revealed that the spreading is mediated by a continuous flow of a thin, basal layer of lamellar cytoplasm [21] directed towards the cell periphery. A general interference with cellular membrane flow might therefore be expected to cause inhibition of hepatocyte spreading, and such inhibition by lysosomotropic amines is demonstrated here. 2. Materials and methods

The process of epithelial cell attachment to glass surfaces studied by reflexion contrast microscopy

The process of attachment was studied in primary mouse kidney epithelial cell cultures by means of reflexion contrast microscopy, a method developed for studying the cell membrane-substrate relationship. The first in a series of events is simple adherence to the substrate, called close contact. This phenomenon is associated with the greatest extension of lamellar cytoplasm and the fewest number of cell nuclei/unit area. The nuclei of such cells are in close contact with the bottom portion of the cell membrane. Approx. 24 h after planting, as the cultures become more crowded, cells develop a different kind of attachment to the substrate—focal contacts—that are correlated with a decrease in lamellar cytoplasm. Cells detached from the substrate after close contact formation readily reattach, while cells detached after formation of focal contacts do not reattach. After incubation for periods greater than 5 days, the dense cultures degenerate and cells lose their attachment to the glass surface.

Fluorescent labelling of cell membranes and cytoplasmic proteins in living cells.

Primary amino groups may be selectively labelled in living cell cytoplasmic components by staining with the covalently binding fluorochrome reagent fluorescamine. The reaction is extremely rapid and occurs at very low reagent concentrations. Cells survive such treatment and gradually remove or metabolize the labelled substances. Nuclei and nucleoli are not labelled, while lamellar cytoplasm, which contains little actual cytoplasm, is well demarcated, thus indicating that the method is useful for studies of cell membrane components. Labelled cell membranes can be prepared for further purification after preliminary external fixation of cell membranes with a supravital polyaldehyde fixative. The use of dimethylsulfoxide as a solvent for fluorescamine allows much longer survival of the cells than the use of acetone as a solvent. In addition, the use of high pH and borate buffer was not necessary to the labelling phenomenon.

Tubulin and actin in paired nonneoplastic and spontaneously transformed neoplastic cell lines in vitro: Fluorescent antibody studies

Pairs of nonneoplastic and spontaneously transformed neoplastic cells were derived from rat, mouse and hamster embryos. The neoplastic cells of each pair had poorly spread cellular morphology, grew in agarose in vitro and produced invasive sarcomas in vivo; the nonneoplastic cells exhibited none of these properties. The distribution of microtubules and microfilament bundles (stress fibers or actin cables) was examined in five such paired lines and in 3T3 and SV40-transformed 3T3 cells by indirect immunofluorescent microscopy of fixed cells treated with rabbit antibody prepared against bovine brain tubulin or guinea pig smooth muscle actin, respectively. Actin cables in all the neoplastic cells appeared thinner and more sparse than in the paired nonneoplastic cells. These differences were also observed in living cells with polarization microscopy. In contrast, microtubules appeared similar in neoplastic and nonneoplastic cells, both in areas of thin peripheral lamellar cytoplasm which allowed a clear visualization of fine, curving microtubules and in regions of thick, central endoplasm which obscured individual microtubules. In fact, the main morphological difference between neoplastic and nonneoplastic cells was the relative amount of lamellar cytoplasm or endoplasm, rather than the appearance of microtubules in either region. Thus the distinctive growth properties and retracted cellular morphology of neoplastic cells in this study did not correlate with decreased or disorganized microtubules, but with thin and sparse actin cables.

Direction of locomotion in clones of non-neoplastic fibroblasts and their neoplastic derivatives

The locomotion of cloned mouse fibroblasts, non-neoplastic and their spontaneously transformed neoplastic derivatives was compared by means of cinephotomicrography. The spontaneous transformants grow as invasive transplantable sarcomas, whereas the non-neoplastic fail to grow as tumors, and do not show the diagnostic characteristics of neoplastic cells in culture; these include certain morphologic alterations, growth in soft agar, and susceptibility to killing by activated macrophages. The non-neoplastic cells tended to maintain the same direction of locomotion in sequential 2.5 h periods, whereas the neoplastic cells did not. Thus, cells in all non-neoplastic lines exhibited a “persisten” walk while cells from the neoplastic lines had a random pattern of locomotion. No relationship between cell density and randomness of locomotion was observed, and the non-neoplastic cells appeared to grow as rapidly as the neoplastic cells. However, the neoplastic cells had higher rates of locomotion possibly associated with their invasive potential in vivo. The deficient amount of lamellar cytoplasm in the neoplastic cells and the high migration rate may account for their random pattern of locomotion.

Effects of antitubulins on the redistribution of crosslinked receptors on the surface of fibroblasts and epithelial cells

Substrate-attached normal mouse fibroblasts, transformed mouse fibroblasts (L strain), and epithelial cells (MPTR strain) were incubated with two ligands crosslinking different groups of the surface receptors: concanavalin A and cationic ferritin. Surface-attached ligands were revealed by an indirect immunofluorescence method. Incubation of control cells with these ligands induced the patching of corresponding surface receptors and the clearing of these receptors from the surface zones located on the lamellar cytoplasm near cell edges actively protruding pseudopodia. Effects of three antitubulins (microtubule-destroying drugs: Colcemid, colchicine, and vinblastine) on the ligand-induced redistribution of receptors were investigated and compared with the previously described effects of these drugs on the distribution of active cell edges. Incubation of normal and transformed fibroblasts with these antitubulins led to the disappearance of nonactive cell edges; the whole cell perimeter became active. Correspondingly, the clearing pattern of the surface receptors of fibroblasts was altered by antitubulins: the cleared area in antitubulin-treated cells formed a circular band along the whole peripheral cell edge. In epithelial cultures, in contrast to fibroblastic ones, antitubulins changed neither the distribution of the active sites of the surface nor the distribution of the areas cleared of crosslinked receptors. Thus, the specific ability of the surface areas located near the active cell edges to become cleared of crosslinked receptors is characteristic not only for the cells with intact microtubules, but also for the cells with microtubules destroyed with antitubulins.

Active cell edge and movements of concanavalin A receptors of the surface of epithelial and fibroblastic cells.

Movements of the receptors of concanavalin A on various parts of the surfaces of substrate-attached cells were compared. Cultured mouse embryo cells of several types were used: epithelial kidney cells and normal and transformed fibroblasts. Initial distribution of receptors was random on the cells of all types. Binding of concanavalin A induced patching of its receptors on all the cell parts. In contrast, directional centripetal movement of receptors was observed only on the surface of certain cell parts, namely, only the surface of peripheral lamellar cytoplasm was cleared of the receptors. Clearing was always initiated in the zone of lamellar cytoplasm located near active cell edges. In epithelial sheets, clearing was not observed on the surface of central cells that had no lamellar cytoplasm. Concanavalin A receptors on the cleared areas of cell surface were gradually restored after the end of incubation. It is suggested that anchoring of the patches of membrane receptors by cortical microfilaments is possible only on the surface of pseudopods and of lamellar cytoplasm but not on the surface of other cell parts. Besides receptor movements, this hypothesis may be explain differences in the adhesive properties of various parts of the cell surface.

Spreading of normal and transformed fibroblasts in dense cultures

Cell spreading in dense cultures of normal mouse embryo fibroblasts and of the two lines of mouse transformed fibroblasts was examined by electron microscopy. The mean number of cell layers in culture and cell population density per unit area of the substrate were detetmined; the mean area of the cell projection on the substratum was found from these data. Normal fibroblasts formed multilayefed sheet in dense culture. The cells in this sheet were well-spread. These cells formed thin lamellae (lamellar cytoplasm) over the surface of other cells and over the intercellular substance. The mean cell area in dense culture was not smaller than that of the cell spread on the substratum in sparse culture. Dense cultures of two transformed lines (M 22 and L) had differing morphologies: cultures of one line (M 22) were multilayered, those of the other line (L) were monolayered. Decreased spreading and almost complete (M 22) or complete (L) absence of lamellar cytoplasm were characteristic of both transformed lines. The mean area of the cell in dense cultures of both lines was several times smaller than that of their normal progenitors. It is concluded that similar reactions leading to the spreading accompanied by the formation of lamellar cytoplasm can be induced by the contact of fibroblast with various surfaces: that of the substratum in sparse culture, that of other cells and of intercellular structures in dense culture. Deficiency of these reactions characteristic for transformed fibroblasts may be responsible for abnormal morphology of their cultures.

A scanning electron microscope study of the early limb-bud in normal andtalpid3mutant chick embryos

ABSTRACTScanning electron microscope studies, supported by transmission electron microscope and light microscope observations, have been made of the wing-bud apex in the region of the apical ectodermal ridge (AER) in both normal and talpid3 mutant embryos.Ln normal embryos: the ectoderm consists of two layers, the periderm and the basal layer, resting upon a basal lamina. The external surface of the periderm cells bears numerous villi, especially numerous at the cell boundaries. In the AER the cells of the basal layer are compacted into a fan-shaped form, remaining as a single layer, though displacement of their nuclei gives the appearance of a stratified epithelium; the periderm cells tend to round up and many are necrotic. Microfilaments and microtubules are present in greater numbers in the AER than in other ectoderm cells and are orientated along the long axis in the very narrow elongated cells which comprise the middle of the ridge. The mesenchymal cells of the mesoderm tend to be flattened, with extensive flattened surface areas separated from each other by long edges of lamellar cytoplasm, from which many long filopodial extensions arise. Often the cells are elongated, with the filopodia arising predominantly at the anterior and posterior ends.In talpid3 embryos : when these were compared with normals no differences were detected in the general ectoderm or in the AER, but in the mesoderm a statistical analysis revealed significant differences in the occurrence of sections through very fine cytoplasmic processes in transmission electron microscope micrographs. Taken in conjunction with visual examination of scanning electron microscope pictures the differences suggested that talpid3 cells have filopodia distributed more extensively around the cell, but that these extensions do not extend so far through the intercellular spaces or produce such fine terminal arborizations as in normal mesenchyme.At the ectodermal/mesodermal boundary there is a web of extracellular material under the basal lamina, separated from the underlying mesoderm by a very narrow gap in normal embryos. Fine cytoplasmic extensions from the mesenchyme cells extend across the gap towards the basal lamina and many are in contact with it. The gap is wider in talpid3 wing-buds and a statistical analysis confirmed that far fewer filopodia approach closely to the basal lamina or make contact with it.The significance of these findings in relation to problems of AER formation and activity and motility of mesenchymal cells in the wing-bud is discussed.

Defective formation of the lamellar cytoplasm by neoplastic fibroblasts (L cells-transformed cells-cell attachment-contact inhibition-scanning electron microscopy-microcinematography).

Isolated cultures of mouse L-cells are similar to those of normal cells in showing contact inhibition of movement and topoinhibition of growth. In mixed cultures with untransformed mouse embryo fibroblasts, their parent strain, however, L cells are able to form colonies above the monolayer of normal fibroblasts, i.e., they have a property characteristic of transformed cells. Analysis of microcinematographic data suggests that the behavior of L cells in mixed cultures is a result of their defective attachment to the substratum. Scanning electron microscopy showed that attachment of a normal fibroblast was accompanied by the formation of a wide ring of flattened cytoplasm spread on the substratum (lamellar cytoplasm). This structure was observed to disintegrate in newly attached L cells. The structure of the lamellar cytoplasm remained abnormal in the fully spread L cells. The mean area of lamellar cytoplasm was 3- to 4-times less in L cells than in normal fibroblasts. It is suggested that deficient formation of lamellar cytoplasm may be the basis of the inability of L cells to interact normally with embryo fibroblasts.