Hormonally induced cell shape changes in cultured rat ovarian granulosa cells

Cultured rat ovarian granulosa cells undergo a dramatic morphological change when exposed to follicle-stimulating hormone (FSH). Exposure to FSH causes the flattened epithelioid granulosa cells to assume a nearly spherical shape while retaining cytoplasmic processes which contact the substrate as well as adjacent cells. This effect of FSH is preceded by a dose-dependent increase in intracellular cAMP, is potentiated by cyclic nucleotide phosphodiesterase inhibitors, and is mimicked by dibutyryl cAMP. Prostaglandins E1 or E2 and cholera enterotoxin also cause the cells to change shape. A subpopulation of the cells responds to luteinizing hormone. These morphological changes, which are blocked by 2,4-dinitrophenol, resemble those produced by treating cultures with cytochalasin B. Electron microscopy shows that the unstimulated, flattened cells contain bundles of microfilaments particularly in the cortical and basal regions. After FSH stimulation, microfilament bundles are not found in the rounded granulosa cell bodies but they are present in the thin cytoplasmic processes. These data suggest that the morphological change results from a cAMP-mediated, energy-dependent mechanism that may involve the alteration of microfilaments in these cells.     

Simulated weightlessness changes the cytoskeleton and extracellular matrix proteins in papillary thyroid carcinoma cells

Studies of astronauts, experimental animals, and cells have shown that, after spaceflights, the function of the thyroid is altered by low-gravity conditions. The objective of this study was to investigate the cytoskeleton and extracellular matrix (ECM) protein synthesis of papillary thyroid cancer cells grown under zero g. We investigated alterations of ONCO-DG 1 cells exposed to simulated microgravity on a three-dimensional random-positioning machine (clinostat) for 30 min, 24 h, 48 h, 72 h, and 120 h (n=6, each group). ONCO-DG 1 cells grown under microgravity exhibited early alterations of the cytoskeleton and formed multicellular spheroids. The cytoskeleton was disintegrated, and nuclei showed morphological signs of apoptosis after 30 min. At this time, vimentin was increased. Vimentin and cytokeratin were highly disorganized, and microtubules (α–tubulin) did not display their typical radial array. After 48 h, the cytoskeletal changes were nearly reversed. The formation of multicellular spheroids continued. In parallel, the accumulation of ECM components, such as collagen types I and III, fibronectin, chondroitin sulfate, osteopontin, and CD44, increased. The levels of both transforming growth factor beta-1 (TGF-β₁) and TGF-β receptor type II proteins were elevated from 24 h until 120 h clinorotation. Gene expression of TGF-β₁ was clearly enhanced during culture under zero g. The amount of E-cadherin was enhanced time-dependently. We suggest that simulated weightlessness rapidly affects the cytoskeleton of papillary thyroid carcinoma cells and increases the amount of ECM proteins in a time-dependent manner.The work of Augusto Cogoli was supported by ETH Zurich, Switzerland.     

Morphologic and phenotypic changes of human neuroblastoma cells in culture induced by cytosine arabinoside

The effects of cytosine-arabinoside (ARA-C) on the growth and phenotypic expression of a new human neuroblastoma (NB) cell line (GI-ME-N) have been extensively tested. Low doses of ARA-C allowing more than 90% cell viability induce morphological differentiation and growth inhibition. Differentiated cells were larger and flattened with elongated dendritic processes; such cells appeared within 48 h after a dose of ARA-C as low as 0.1 micrograms/ml (about 1000-fold lower than the conventional clinic dose). The new morphological aspect reached the maximum expression after 5-6 days of culture being independent from the addition of extra drug to the culture. A decrease in [3H]thymidine incorporation was also observed within 24 h and the cell growth was completely inhibited on the sixth day. Moreover, ARA-C strongly inhibited anchorage-independent growth in soft agar assay. Membrane immunofluorescence showed several dramatic changes in NB-specific antigen expression after 5 days of treatment with ARA-C. At the same time ARA-C also modulated cytoskeletal proteins and slightly increased catecholamine expression. These findings suggest that noncytotoxic doses of ARA-C do promote the differentiation of GI-ME-N neuroblastoma cells associated with reduced expression of the malignant phenotype.     

Longterm conditions of mimicked weightlessness influences the cytoskeleton in thyroid cells

Weightlessness influences the human immune and hormone system, reduces bone mass, leads to muscle atrophy and cardiac atrophy. Effects on control mechanisms for proliferation, programmed cell death and differentiation are well documented. The principal aim of this study was to investigate changes of the cytoskeleton in thyroid cells cultured in vector-averaged gravity under clinostat rotation. After 12 hours the formation of multicellular spheroids started. An increase of extracellular matrix proteins and beta 1-integrin was observed. Laser scanning confocal microscopy of ML-1 follicular thyroid carcinoma cells and normal thyroid HTU-5 cells immunostained with anti-cytokeratin to demonstrate these intermediate filaments revealed that cytokeratin filaments extended from centers, were thickened, coalesced and shortened as compared to control cells. Moreover, vimentin was highly disorganized. The vimentin network formed a coiled aggregate closely associated with the nucleus. Western blot analyses of talin, alpha- and beta-tubulin showed a clear increase of these proteins in cells cultured under simulated 0 g. Our data suggest that the effects of microgravity on cultured human thyroid cells are accompanied by noticeable functional cellular changes. Future studies to clarify the pathway that regulate the observed integrin activation and the mechanisms by which they function have to be performed.     

Cyclic AMP level of human thyroid cells in monolayer culture. TSH induced refractoriness to TSH action.

Thyroid cells from euthyroid patients with Graves' disease were cultured in a chemically defined medium. The cells preserved the ability to respond to TSH with 8-fold increase in cyclic AMP concentration. This cyclic AMP response to TSH was diminished by prior exposure of cells to TSH. The decrease in cyclic AMP response to TSH induced to TSH was reversible, was not associated with a similar decrease to cyclic AMP response to PGE1, and could not be attributed to increased phosphodiesterase activity or to decreased adenyl cyclase activity. The partial resistence to TSH stimulation of thyroid cells previously exposed to TSH may be due to changes in the TSH receptor, possibly caused by TSH itself.     

Ultrastructural changes induced by ACTH in normal adrenocortical cells in culture

The effects of ACTH, its o-nitrophenyl sulfenyl derivative (NPS-ACTH) and dibutyryl cyclic AMP (dbc AMP) on the ultrastructural morphology of adrenocortical cells of adult rats in monolayer culture have been investigated. NPS-ACTH, which has previously been shown to stimulate steroidogenesis but not cAMP synthesis in adrenal cells, induced the same characteristic transformation of mitochondrial architecture as produced by ACTH or high concentrations of dbcAMP. All three agents caused the disappearance of electron-opaque granules present in the mitochondria of unstimulated cells. It was found that these granules could be extracted with EGTA (ethylene glycol-bis(beta-aminoethyl ether) N,N,N',N'-tetraacetate). These results are discussed in the light of the known importance of calcium ions in the actions of ACTH.     

Dynamics of the cytoskeleton of epidermal cells in situ and in culture

Summary The cytoskeleton of primary tissue-culture cells from the epidermis of Xenopus laevis tadpoles was investigated by phase-contrast, immunofluorescence, and electron microscopy. The connection between the arrangement of different types of filaments and the mechanical properties of the epidermis is discussed. The bilayered epidermis attains stability from thick bundles of tonofilaments interconnecting the basal desmosomes. Twisting of tonofilaments around each other can explain the occurrence of elastic filamentous curls forming a meshwork braced between rows of small desmosomes in the apical region of the epidermis. Actin is arranged as a diffuse meshwork and sometimes forms bundles intermingling with tonofilament bundles. Surface membranes and rows of small desmosomes are delineated by actin and contain -actinin. Actin raises the tension for rounding and spreading of cells. Microtubules stabilize already well-developed lamellae.     

Morphological and functional differentiation of human thyroid cells in collagen gel culture

In order to study the expression of the morphological and functional characteristics of human thyroid cells, 3-dimensional cultures were carried out in collagen gel. This substrate allows the cells to retain their organization in follicles with a normal polarity. Cellular polarities appeared normal at the time of collagen embedding, but there was a delay of 4-5 days in culture before the maximal TSH stimulation of 125I- uptake and of cAMP accumulation occurred. In normal and adenoma-derived cells, 125I- uptake, which could be increased by TSH, was demonstrated. cAMP accumulated in the culture medium and thyroglobulin was secreted into the follicle lumen. Of the 4 differentiated carcinomas for which the 72-hr uptake of 125I- was measured, only 2 displayed slight 125I- uptake and response to TSH. Thus, human thyroid cells exhibit better morphological and functional differentiation in collagen gel culture than in monolayer culture. Furthermore, in a variety of pathological cases studied, the expression of specific characteristics in culture varied in a fashion similar to differences observed in vivo.     

Role of the cytoskeleton in the morphological normalization of transformed cells in culture

The role of the cytoskeleton in morphological normalization of transformed cells was studied. Mouse cells of the L197/6 clonal line were fused by polyethylene glycol and replated. The multinuclear cells were more spread than control ones: the ratio of the cell-occupied area to the number of the nuclei increased 2-3 times as a result of multinucleation. Instead of the spindle-like morphology typical for control cells they became star-like with larger lamellar regions located between radially oriented cell processes. According to the immunofluorescent data these processes contained thick bundles of microtubules and intermediate filaments. Destruction of these bundles with colcemide led to a decrease in the area occupied by multinuclear cells but did not change significantly the area occupied by control cells. The role of microtubules and intermediate filaments in cell spreading is discussed.     

Dimethylsulfoxide maintains human thyroid cells in suspension culture, facilitating synthesis and release of thyroid hormone

Usually, human thyrocytes in primary culture rapidly lose their thyroid function and fail to synthesize or release thyroid hormone after 3-5 days of culture. By culturing thyroid follicles obtained from patients with Graves' disease in medium supplemented with TSH and a low concentration of fetal calf serum (1%), thyrocytes can maintain thyroid function for several days. We have found that the addition of dimethylsulfoxide to culture medium (1.7%) furthermore enhanced and maintained thyroid function (de novo synthesis and release of [125I] thyroxine) for more than 13 days, probably by inhibiting dedifferentiation of thyrocytes. The present bioassay will be also useful for detecting thyroid stimulating immunoglobulin in patients with Graves' disease.     

Benzamide-induced changes in the actin cytoskeleton in human skin fibroblasts.

The incubation of human skin fibroblasts in the presence of 10 mM benzamide in Joklik's modification of Eagle's Minimal Essential Medium caused an extensive reorganization of actin filaments. The disappearance of stress fibers and changes in cell morphology were observed, whereas no changes in the microtubule architecture were noticed. The observed effects appeared fully reversible within 3 hours after the removal of benzamide. The results are discussed in relation to the two known activities of benzamide as an anaesthetic and an inhibitor of ADP-ribosylation.     

Reexpression of blood group ABH antigens on the surface of human thyroid cells in culture

Using indirect immunofluorescence (IFL) on viable human thyroid cultures, it has been shown that, although adult follicular cells do not express blood group ABH antigens in vivo, they invariably reexpress the corresponding antigens on the cell surface when cultured in monolayers, even for very short periods. The absence of blood group antigens on noncultured thyroid cells was confirmed by negative IFL on cell suspensions obtained after enzymatic digestion of the glands, whereas these antigens were readily demonstrable on cell suspensions obtained by trypsinization of established monolayers. The quantitative expression of ABH antigens on individual thyroid cells was variable and the cell-surface IFL pattern due to binding of blood group isoantibodies was different from that given by organ-specific thyroid autoantibodies on viable cultures. Reexpression of blood group antigens by cultured thyroid cells could not be related to the secretor status of the donors, the presence of a particular source of serum in the culture medium or cell division in vitro. After 2-3 wk in culture, thyroid cells became morphologically dedifferentiated and no longer displayed blood group antigens, though they still expressed cell- surface beta 2-microglobulin. Fibroblasts present in the primary thyroid cultures were invariably negative for ABH antigens. These results demonstrate that the surface antigenic repertoire of cultured human cells is not necessarily identical to that present on the same cells in vivo. Furthermore, the possibility that blood group natural isoantibodies bind to the cell surface must be taken into account in experiments in which cultured thyroid cells are exposed to human sera.     

Morphological changes of human neuroblastoma cells induced by human gamma interferon

The treatment of GOTO cells, originated from human neuroblastoma, with recombinant human interferon-gamma (rHuIFN-gamma) induced the morphological changes: the extension and bifurcation of neurites and the multinucleated giant cell formation. The treatment of KP-N-RT cells, originated from human neuroblastoma, with rHuIFN-gamma also induced the similar morphological changes. The treatment of these cells with natural HuIFN-gamma also induced the same morphological changes, but those with recombinant human leukocyte interferon (rHuIFN-alpha A), recombinant human fibroblast interferon (rHuIFN-beta) and recombinant murine interferon-gamma (rMuIFN-gamma) did not induce it. The rHuIFN-gamma and the rHuIFN-beta inhibited more strongly the growth of GOTO and KP-N-RT cells than the rHuIFN-alpha A. This suggests that the morphological changes of these neuroblastoma cells are not simply due to the cell growth inhibition, but due to the property which only the rHuIFN-gamma possesses.     

Calcium-induced changes in cytoskeleton and motility of cultured human keratinocytes

In normal epidermis keratinocytes migrate upward from the basal layer as they undergo terminal differentiation, yet they also have the capacity for lateral movement during wound healing. The purpose of our experiments was to investigate these two types of movement by manipulating the calcium ion concentration of the medium so that keratinocytes formed monolayers (0.1 mM calcium) or stratified sheets (2.0 mM calcium). Time-lapse video recording indicated that keratinocytes in low-calcium medium were laterally more motile than keratinocytes in normal medium. This was consistent with the ultrastructural appearance of the cells and the lack of desmosomal junctions, determined by scanning and transmission electron microscopy. During calcium-induced stratification keratinocytes moved upward from the basal layer by gliding over their neighbors and forming contacts with other suprabasal cells. Keratinocytes in low-calcium medium migrated into wounds made in the cultures, a process which was inhibited by monensin; however, stratified keratinocytes in normal medium did not enter wounds. Cytochalasin D caused rapid cell rounding and disruption of actin filaments in keratinocytes grown in low-calcium but not in normal medium, indicating more rapid treadmilling of actin and consistent with the greater motility of keratinocytes in low-calcium medium. Our results suggest that desmosome formation may place constraints on the movement of individual keratinocytes and that the actomyosin cytoskeleton is involved in lateral migration.     

Mevalonate controls cytoskeleton organization and cell morphology in thyroid epithelial cells

Blockade of mevalonate synthesis by the 3-hydroxy-3-methylglutaryl Coenzyme A reductase inhibitor mevinolin (lovastatin) causes FRTL-5 thyroid cells to undergo significant morphological changes; these include a transition from a flat, polygonal to a round shape, the development of cytoplasmic arborizations, and the loss of contact between neighboring cells. Immunofluorescence studies of cytoskeletal structures show that, at early times after administering the drug, and before the round phenotype develops, stress fibers disassemble while the peripheral actin filaments, which are adjacent to the cytoplasmic face of the plasma membrane, appear largely unaffected. Subsequently, when this cortical actin network becomes fragmented, cells start to round up and become separated from neighbors. Microtubules become disconnected from the plasma membrane and retract toward the cell center, although they do not appear depolymerized; indeed, at this stage, cytoplasmic elongations contain mostly intact microtubules. After exposure to mevinolin FRTL-5 cells also lose vinculin-related substrate contacts. Treatment of cells with either cycloheximide or colchicine abolishes morphological changes induced by mevinolin, suggesting that ongoing protein synthesis and microtubule integrity are prerequisites for the drug to be effective. Both cytoskeletal and morphological perturbations can be reversed by mevalonate, but not by cholesterol or the non-sterol derivatives of mevalonate such as dolichol, ubiquinone, and isopentenyladenine, individually or in combination. It is suggested that mevalonate deficiency may impair formation of isoprenylated proteins important for cytoskeletal organization and stability. © 1993 Wiley-Liss, Inc.     

Prolonged culture of cells from normal human thyroid tissue and toxic goiters

Normal human thyroid cells and cells from patients with Grave's disease were cultured for 5 months (11 passages) in vitro. Both normal and diseased thyreocytes, similar in morphology, proliferated actively and responded to thyrotropin stimulation by cytoplasmic arborization of a part of the population. Slight inhibition of mitotic activity was present under the influence of thyrotropin.     

The cytoskeleton of Drosophila-derived Schneider line-1 and Kc23 cells undergoes significant changes during long-term culture

Insect cell cultures derived from Drosophila melanogaster are increasingly being used as an alternative system to mammalian cell cultures, as they are amenable to genetic manipulation. Although Drosophila cells are an excellent tool for the study of genes and expression of proteins, culture conditions have to be considered in the interpretation of biochemical results. Our studies indicate that significant differences occur in cytoskeletal structure during the long-term culture of the Drosophila-derived cell lines Schneider Line-1 (S1) and Kc23. Scanning, transmission-electron, and immunofluorescence microscopy studies reveal that microfilaments, microtubules, and centrosomes become increasingly different during the culture of these cells from 24 h to 7–14 days. Significant cytoskeletal changes are observed at the cell surface where actin polymerizes into microfilaments, during the elongation of long microvilli. Additionally, long protrusions develop from the cell surface; these protrusions are microtubule-based and establish contact with neighboring cells. In contrast, the microtubule network in the interior of the cells becomes disrupted after four days of culture, resulting in altered transport of mitochondria. Microtubules and centrosomes are also affected in a small percent of cells during cell division, indicating an instability of centrosomes. Thus, the cytoskeletal network of microfilaments, microtubules, and centrosomes is affected in Drosophila cells during long-term culture. This implies that gene regulation and post-translational modifications are probably different under different culture conditions.