Some of eukaryotic elongation factor 2 is colocalized with actin microfilament bundles in mouse embryo fibroblasts

Indirect immunofluorescent microscopy was used to study the distribution of eukaryotic elongation factor 2 (EF-2) in cultured mouse embryo fibroblasts. The perinuclear area (endoplasm) of all the cells and many straight cables running along the whole cytoplasm were stained with monospecific goat or rabbit antibodies to rat liver EF-2. Double staining of the cells with antibodies to EF-2 and rhodaminyl-phalloidin (used for actin microfilament detection) showed that EF-2 containing cables coincided with bundles of actin microfilaments. Not all actin microfilament bundles contained EF-2: sometimes EF-2 was not observed in bundles running along the cell edges or in actin microfilament junctions. Triton X-100 extracted most of EF-2 from the cells and no actin microfilament bundles were stained with the EF-2 antibodies in the Triton-extracted cells. Thus, in mouse embryo fibroblasts EF-2 can be found along actin microfilament bundles, but it is unlikely to be their integral protein.     

Sensitivity of Fibroblasts and Their Cytoskeletons to Substratum Topographies: Topographic Guidance and Topographic Compensation by Micromachined Grooves of Different Dimensions

Fibroblasts alter their shape, orientation, and direction of movement to align with the direction of micromachined grooves, exhibiting a phenomenon termed topographic guidance. In this study we examined the ability of the microtubule and actin microfilament bundle systems, either in combination with or independently from each other, to affect alignment of human gingival fibroblasts on sets of micromachined grooves of different dimensions. To assess specifically the role of microtubules and actin microfilament bundles, we examined cell alignment, over time, in the presence or absence of specific inhibitors of microtubules (colcemid) and actin microfilament bundles (cytochalasin B). Using time-lapse videomicroscopy, computer-assisted morphometry and confocal microscopy of the cytoskeleton we found that the dimensions of the grooves influenced the kinetics of cell alignment irrespective of whether cytoskeletons were intact or disturbed. Either an intact microtubule or an intact actin microfilament-bundle system could produce cell alignment with an appropriate substratum. Cells with intact microtubules aligned to smaller topographic features than cells deficient in microtubules. Moreover, cells deficient in microtubules required significantly more time to become aligned. An unexpected finding was that very narrow 0.5-μm-wide and 0.5-μm-deep grooves aligned cells deficient in actin microfilament bundles (cytochalasin B-treated) better than untreated control cells but failed to align cells deficient in microtubules yet containing microfilament bundles (colcemid treated). Thus, the microtubule system appeared to be the principal but not sole cytoskeletal substratum-response mechanism affecting topographic guidance of human gingival fibroblasts. This study also demonstrated that micromachined substrata can be useful in dissecting the role of microtubules and actin microfilament bundles in cell behaviors such as contact guidance and cell migration without the use of drugs such as cytochalasin and colcemid.     

Microfilament bundles in cultured cells : Correlation with anchorage independence and tumorigenicity in nude mice

The distribution of actin microfilament bundles in cell lines 3T3B, CHO, HeLa and CLID extracted with 0.1% Triton X-100 was examined by indirect immunofluorescence using human actin antibodies and by electron microscopy of whole cells grown directly on support grids. Anchorage dependence as determined by growth in soft agar and tumorigenicity in nude mice was also investigated. Immunofluorescent staining showed that CHO and HeLa cells have normal numbers and distributions of actin microfilament bundles as compared with similarly spread control 3T3B cells. A significant fraction of the mouse CLID cells showed comparable numbers of microfilament bundles as 3T3B cells but their distribution was markedly different. In many cases the bundles radiated from a region close to the cell's centre or near its projections and usually penetrated the projections. The presence of diffuse staining in 4% of the cell population also indicated the existence in these cells of disorganized actin. Electron microscope studies of well spread regions of negatively-stained, Triton-extracted cells corroborated the observations made with the immunofluorescence technique. In 3T3B, CHO and CLID cells abundant microtubules were found, colinearly arranged with actin filaments in the thin cytoplasmic extensions. While CLID, CHO and HeLa cells showed the capacity to grow in soft agar, only CLID and HeLa cells produced tumours in athymic nude mice. The observations suggest that a reduction or disorganisation of the actin microfilament bundles may not in itself be essential at least for the non-virally transformed cells studied to show anchorage independence or to produce tumours in nude mice.     

Destruction of microfilament bundles in mouse embryo fibroblasts treated with inhibitors of energy metabolism

Immunofluorescence with an antiactin antibody and electron microscopy were used to study the distribution of actin in cultured mouse fibroblasts during treatment with inhibitors of energy metabolism. The inhibitors induce gradual disorganization of actin-containing microfilament bundles. At the first stage of the process the bundles degrade into separate fragments; later only small patches of actin can be found in the inhibitor-treated cells. This transformation takes about 90 min and is fully reversible as microfilament bundles are recovered after incubation of the cells in the inhibitor-free growth medium. The inhibitors do not alter actin distribution in the presence of glucose. This shows that their action is due to a reduction of the ATP level in the cells. A 90 min incubation with the inhibitors does not markedly alter either the cell shape or the microtubule system. Inhibitors of the energy metabolism prevent cytochalasin action on cells. Cytochalasin B (CB) or cytochalasin D (CD) rapidly disorganize the microfilament bundles and cause cell arborization. However, microfilament bundle destruction in the cells incubated in the mixture of cytochalasin and any of the inhibitors requires 90 min and is not accompanied by dramatic changes in the cell morphology, so the process is indistinguishable from microfilament bundle destruction in the presence of the inhibitors alone.     

Distribution of actin and tubulin in cells and in glycerinated cell models after treatment with cytochalasin B (CB)

The organization of microfilaments and microtubules in cultured cells before and after the addition of cytochalasin B (CB) was studied both by electron microscopy and immunofluorescence microscopy using antibodies specific for actin, tubulin and tropomyosin. CB induces a rapid disorganization of normal microfilament bundles. Star-like patches of actin and tropomyosin are visualized in immunofluorescence microscopy and dense aggregates of condensed microfilaments are seen in electron microscopy. The integrity of the microtubules is not changed by CB treatment. Addition of CB to glycerinated cells, in contrast to normal cells, does not result in the disorganization of microfilament bundles. CB-treated glycerinated models can still contract upon addition of ATP. Thus the CB-induced rearrangement of microfilament bundles occurs only in vivo and not in glycerinated cell contractility models.     

Disorders of the actin cytoskeleton in transformed epithelial cells

The actin cytoskeleton of 8 transformed epithelial cell lines was studied using electron microscopy of platinum replicas. Seven of these lines belonged to the IAR series of rat liver epithelial cells, being at different stages of neoplastic progression. One cell line (FBT) was derived from the epithelium of bovine fetal trachea. The extent of actin cytoskeleton alteration in cell lines studied has been shown to correlate with other signs of neoplastic transformation. Among various actin-containing cell structures (microfilament bundles, actin meshwork at active edges, cell-cell adherence junctions, and endoplasmic microfilament sheath) the latter was the most sensitive to transformation. The loosening of the sheath and the alteration of its fine structure were observed in all the cell lines. The degree of these changes increased in the following order: FBT; non-tumorigenic IAR lines; IAR lines transformed in vitro; IAR lines obtained from the latter by single or double selection in vivo. The alteration of sheath was the only disturbance of actin cytoskeleton in FBT cells, whereas in other groups of epithelial cell lines some other changes occurred. These involved disruption of actin-containing intercellular junctions, the cell polarization accompanied by progressive shortening of length of the cell active edge containing actin meshwork, and disappearance or reorganization of microfilament bundles.     

Distribution of microfilament bundles during rotation of the nucleus in 3T3 cells treated with monensin

Cytoskeletal aspects of monensin-treated 3T3 cells with rotating nuclei were studied by immunofluorescence. The pattern of intermediate filaments and microtubules appeared unchanged when compared with control cells having a stationary nucleus. In contrast, the actin microfilament bundles appeared to have a consistent distribution in cells with rotating nuclei. Typically, we did not find long microfilament bundles that traverse the length of the cytoplasm of cells that were fixed at the time of nuclear rotation. Instead, there was a local distribution of short microfilament bundles situated ventrally to the nucleus and oriented at various angles to one another and to the predominant distribution of microfilament bundles in the cell. The observations suggest that the actin cytoskeleton is reorganized locally before or during rotation of the nucleus.     

Actin and tubulin in teratocarcinoma cells. Amount and intracellular organization upon cytodifferentiation.

Embryonal carcinoma (EC) cells and differentiated derivatives grown in tissue culture have rather similar amounts of actin and tubulin. Indirect immunofluorescent microscopy with antibodies to actin shows striking differences in the actin organization in the different teratocarcinoma derivatives. In the EC cells, actin is found predominantly in ruffles and in surface protrusions, as well as in the cytoplasm, but microfilament bundles are not seen. Some of the differentiated clones contain strongly stained microfilament bundles; others contain actin arrangements which appear to be characteristic of the particular cell type. Indirect immunofluorescence microscopy with antibody to tubulin suggests that cytoplasmic microtubules are present both in the EC cells and in the various differentiated states studied. However, the ease with which microtubules can be documented is dependent on how cells are spread on the substratum. During in vitro differentiation of EC cells, changing patterns of actin distribution appear. Cells at the edge of the colony show the characteristic changes in microfilament and microtubular organization before those in the center.     

Staurosporine induces dissolution of microfilament bundles by a protein kinase C-independent pathway

The protein kinase C (PKC) inhibitor staurosporine was found to dramatically alter the actin microfilament cytoskeleton of a variety of cultured cells, including PTK2 epithelial cells, Swiss 3T3 fibroblasts, and human foreskin fibroblasts. For example, PTK2 cells exposed to 20 nM staurosporine exhibited a progressive thinning and loss of cytoplasmic actin microfilament bundles over a 60-min period. During this time microtubule and intermediate filament systems remained intact (as shown by immunofluorescence and at higher resolution by photoelectron microscopy), and the cells remained spread even though microfilament bundles were absent. Higher doses of staurosporine or longer exposure times at lower doses resulted in morphological alterations, but even severely arborized cells recovered normal morphology and actin patterns after a wash and an incubation for several hours in fresh medium. The actin filament disruption induced by staurosporine was distinguishable from the actin reorganization induced by exposure to the tumor promoter (and activator of PKC) phorbol myristate acetate (PMA). Swiss 3T3 cells made deficient in PKC by prolonged exposure to PMA (PKC down-regulation) exhibited actin alterations in response to staurosporine which were comparable to those in cells which had not been exposed to the phorbol ester. In a parallel control experiment, the actin cytoskeleton of PKC-deficient 3T3 cells was unaffected in response to PMA, consistent with down-regulation of this kinase. While the exact mechanism of staurosporine-induced actin reorganization remains to be determined, the observed effects of staurosporine on PKC-deficient cells make a role for PKC unlikely. These results indicate the need for care when staurosporine is employed as an inhibitor of protein kinase C in studies involving intact cells.     

pp60v-src association with the cytoskeleton induces actin reorganization without affecting polymerization status

The mechanism by which Rous sarcoma virus (RSV) induces a reorganization of actin and its associated proteins and a reduction in microfilament bundles is at present poorly understood. To examine the relationship between the organization of the microfilament system and the polymerization state of actin after transformation, we have investigated these changes in a Rat-1 cell line transformed by LA29, a temperature-sensitive (ts) mutant of RSV. Parallel immunofluorescence and biochemical analysis demonstrated that LA29 pp60v-src was ts for tyrosine kinase activity and cytoskeletal association. Changes in the distribution and organization of actin, alpha-actinin and vinculin were dependent on the association of a kinase-active pp60v-src molecule with the detergent-insoluble cytoskeleton. Whilst there was a transformation-dependent loss of microfilament bundles, biochemical quantitation demonstrated that the polymerization state of the actin in both detergent-soluble and insoluble fractions of these cells grown at temperatures either permissive or restrictive for transformation was quantitatively unchanged. These results indicate that the loss of microfilament bundles after transformation is not due to a net depolymerization of filamentous actin but rather to a reorganization of polymeric actin from microfilament bundles and stress fibers to other polymeric forms within the cell. The polymeric nature of the actin in these cells was confirmed by electron microscopy of cytoskeletons and substrate-adherent membranes.     

The detergent-resistant cytoskeleton of tissue culture cells includes the nucleus and the microfilament bundles

Mouse 3T3 and chick embryo cells grown in monolayers have been treated with the non-ionic detergents, NP40 or Triton X-100, to give “nuclear monolayers”. Immunofluorescence microscopy with antibodies against actin shows that most of the microfilament bundles remain detergent resistant and form part of the cell's cytoskeleton. Sodium dodecylsulfate (SDS) polyacrylamide gel electrophoresis of cytoskeleton preparations from chick embryo fibroblasts show the following major proteins: the lower molecular weight histones, a protein coelectrophoresing with actin and a protein, X, of molecular weight approx. 58 000 which is different from tubulin. Thus, at least in well spread cells containing a strongly developed system of microfilamentous bundles, the detergent-resistant cytoskeleton includes the nucleus, large amounts of the 58 000 molecular weight protein and the microfilamentous bundles. The importance of the existence of microfilamentous actin in the cytoskeleton is discussed in relation to previous reports on the existence of actin as a major non-histone protein in the nucleus.     

Visualization of the same PtK2 cytoskeletons by both immunofluorescence and low power electron microscopy.

A procedure is described which allows the examination of the cytoskeleton of a single PtK2 cell first by immunofluorescence and then by electron microscopy after staining with uranyl acetate. The immunofluorescent patterns of these detergent resistant cytoskeletons elicited with various monospecific antibodies closely resemble the patterns found in whole cells. Comparison of the immunofluorescence and electron micrographs directly supports the previous assignments of actin, myosin, filamin, α-actinin and tropomyosin as proteins associated with microfilament bundles in non-muscle cells. Actin is also found associated with a fine lattice-like structure present both in the ruffles and lying above the microfilament bundles in the cell body. The tonofilament bundles present in PtK2 cytoskeletons are not decorated by antibodies directed against the proteins associated with microfilament bundles. Antibodies directed against tonofilaments decorate specifically this system and not the microfilament bundles.     

Modulation by retinyl acetate of microfilament bundle formation in C3H/10T1/2 cells

Retinyl acetate has been previously shown to inhibit carcinogen-induced neoplastic transformation in 10T1/2 cells and to accentuate many aspects of the nontransformed phenotype. Scanning electron microscopy of logarithmic phase 10T1/2 cells treated for 3 days with 0.3 micrograms/ml retinyl acetate revealed that this treatment caused extensive flattening of cells to the plastic substrate. In contrast the tumor promoter tetradecanoyl phorbol acetate, which antagonizes the antineoplastic activity of retinyl acetate, caused cell rounding and completely inhibited the action of retinyl acetate on cell morphology. During this same time course, the formation of microfilament bundles was also found to be modulated by retinyl acetate. Transmission electron micrographs of unsectioned peripheral regions of flattened cells showed that while the unit density of microfilament bundles was not influenced, the thickness of bundles, particularly those with a diameter of 100 nm or more, was increased by retinyl acetate. Tetradecanoyl phorbol acetate had little effect on microfilament bundle diameters but did partially antagonize the action of retinyl acetate. To determine if this increase was associated with an increase in total actin/cell, total cell proteins, and proteins not extractable by glycerol-triton extraction, were subjected to sodium dodecylsulfate/ polyacrylamide gel electro-phoresis. It was found that while total cellular actin was not increased by retinyl acetate, the proportion of nonextractable actin (which includes microfilament bundles) increased from 65% to 88% of total actin. This increase was not inhibited by inhibitors of protein or RNA synthesis. These studies again demonstrate that retinyl acetate accentuates the nontransformed phenotype of 10T1/2 cells; it is hypothesized that these actions are related to the antineoplastic activity of retinoids.     

Stress fibers in situ in proximal tubules of the rat kidney

Actin bundles in proximal tubules of the rat kidney were examined by immunofluorescence and confocal laser microscopy with special reference to their three-dimensional distribution and identification as stress fibers. Renal tubular segments were prepared from the fresh renal cortex by simple homogenization and centrifugation, and fixed in formaldehyde for staining with fluorescent dye-labeled phalloidin. Segments of the proximal tubules could be identified easily on the bases of their diameter, the height of epithelial cells and prominent brush borders. Confocal laser microscopy clearly demonstrated the overall distribution of actin bundles in the whole-mount proximal tubular segments. Actin bundles in the basal cytoplasm of epithelial cells were observed to run parallel to each other and at a right angle to the tubular axis. In the stereo views reconstructed from serial optical sections, the basal actin bundles appeared as straight rods with both ends tapered. They varied in length and width and extended rather short distances of not more than 10 microns. Often, two or more actin bundles were longitudinally aligned in tandem. Some bundles showed irregular bandings along their length. Each bundle was composed of tightly packed actin filaments which could be decorated with heavy meromyosin subfragment-1 to display a bi-directional arrangement within the bundle. Immunostaining of cryostat sections showed that actin bundles contained myosin and vinculin. Enzymatically isolated proximal tubules contracted upon addition of Mg-ATP. These observations collectively suggest that the actin bundles at the base of renal proximal tubule epithelial cells can be listed among the examples of stress fibers in situ.     

Protein kinase C inhibitor H-7 alters the actin cytoskeleton of cultured cells

The effects of the protein kinase C inhibitor H-7 on the actin cytoskeleton of cultured cells (Swiss 3T3 and PTK2) are described. As documented by fluorescence microscopy and the higher-resolution technique of photoelectron microscopy, the effects are rapid and dramatic; exposure to 30 μM H-7 in culture medium for less than 6 min is sufficient to induce a significant reduction in the numbers and thickness of actin microfilament bundles and alterations in the morphology of cell-cell boundaries in PTK2 cells. One-hour exposure to 30 μM H-7 results in nearly complete depletion of normal actin microfilament bundles from all of the cell types examined, without dramatic changes in overall cell shape. The intermediate filament and microtubule cytoskeletal networks did not appear to be affected to any extent over the times and doses examined. Forty-five minutes of exposure of Swiss 3T3 cells to 200 μM of either HA1004 (which is comparable to H-7 with respect to inhibition of cyclic nucleotide dependent kinases) or to the protein kinase C inhibitor sangivamycin did not induce the actin alterations characteristic of H-7. In addition, depletion of protein kinase C from Swiss 3T3 cells by means of phorbol ester-induced down-regulation did not prevent the effects of H-7 on the actin cytoskeleton. These results demonstrate that the protein kinase C inhibitor H-7 has a specific and rapid effect on the actin cytoskeleton, and furthermore H-7 may have biochemical effects beyond those mediated by inhibition of protein kinase C or the cyclic nucleotide dependent kinases.     

Localization of myosin, actin, and tropomyosin in rat intestinal epithelium: immunohistochemical studies at the light and electron microscope levels

Myosin, tropomyosin, and actin were localized in the epithelial cells of rat intestine by means of specific antibodies to chicken gizzard smooth muscle myosin, tropomyosin, and actin by immunohistochemical studies at both the light and electron microscope levels (unlabeled antibody enzyme technique). The pattern of antibody staining was the following (a) Anti-actin was associated with the microfilament bundles of the microvilli in their entire length, as well as with the microfilament network in the terminal web. (b) Anti-myosin was concentrated along the rootlets of the microvillar microfilament bundles and within the filamentous feltwork forming the terminal web. (c) Anti-tropomyosin showed a distribution similar to that of anti- myosin. In addition, the three antibodies also labeled the subplasmalemmal web underneath the cell membrane bordering on the basal lamina. Utilizing the above ultrastructural findings, we wish to propose a functional model of microvillar contraction.     

Overexpression of human fibroblast caldesmon fragment containing actin- , Ca++/calmodulin-, and tropomyosin-binding domains stabilizes endogenous tropomyosin and microfilaments

Fibroblast caldesmon is a protein postulated to participate in the modulation of the actin cytoskeleton and the regulation of actin-based motility. The cDNAs encoding the NH2-terminal (aa.1-243, CaD40) and COOH-terminal (aa.244-538, CaD39) fragments of human caldesmon were subcloned into expression vectors and we previously reported that bacterially produced CaD39 protein retains its actin-binding properties as well as its ability to enhance low M(r) tropomyosin (TM) binding to actin and to inhibit TM-actin-activated HMM ATPase activity in vitro (Novy, R. E., J. R. Sellers, L.-F. Liu, and J. J.-C. Lin. 1993. Cell Motil. Cytoskeleton. 26:248-261). Bacterially produced CaD40 does not bind actin. To study the in vivo effects of CaD39 expression on the stability of actin filaments in CHO cells, we isolated and characterized stable CHO transfectants which express varying amounts of CaD39. We found that expression of CaD39 in CHO cells stabilized microfilament bundles as well as endogenous TM. CaD39-expressing clones displayed an increased resistance to cytochalasin B and Triton X-100 treatments and yielded increased amounts of TM-containing actin filaments in microfilament isolation procedures. In addition, analysis of these clones with immunoblotting and indirect immunofluorescence microscopy with anti-TM antibody revealed that stabilized endogenous TM and enhanced TM-containing microfilament bundles parallel increased amounts of CaD39 expression. The increased TM observed corresponded to a decrease in TM turnover rate and did not appear to be due to increased synthesis of endogenous TM. Additionally, the phenomenon of stabilized TM did not occur in stable CHO clones expressing CaD40. Therefore, it is likely that CaD39 can enhance TM's binding to F-actin in vivo, thus reducing TM's rate of turnover and stabilizing actin microfilament bundles.     

Formation of microfilament bundles in the tumor cell interphase nuclei of a rat neurinoma exposed to dimethyl sulfoxide

The action of 15% dimethyl sulfoxide (DMSO) on the ultrastructure of the rat neurinoma cells (line NGUK-I) has been studied. The agent induced the formation of microfilament bundles in interphase nuclei after 30-60 min of treatment. The microfilament bundles revealed are suggested to be actin.     

Identification of the cytoskeletal proteins in lens-forming cells, a special epithelioid cell type

Proteins of contractile and cytoskeletal elements have been studied in bovine lens-forming cells growing in culture as well as in bovine and murine lenses grown in situ by immunofluorescence microscopy using antibodies to the following proteins: actin, myosin, tropomyosin, α-actinin, tubulin, prekeratin, vimentin, and desmin. Lens-forming cells contain actin, myosin, tropomyosin, and α-actinin which in cells grown in culture are enriched in typical cable-like structures, i.e. microfilament bundles. Antibodies to tubulin stain normal, predominantly radial arrays of microtubules. In the epithelioid lens-forming cells of both monolayer cultures grown in vitro and lens tissue grown in situ intermediate-sized filaments of the vimentin type are abundant, whereas filaments containing prekeratin-like proteins (‘cytokeratins’) and desmin filaments have not been found. The absence of cytokeratin proteins observed by immunological methods is supported by gel electrophoretic analyses of cytoskeletal proteins, which show the prominence of vimentin and the absence of detectable amounts of cytokeratins and desmin. This also correlates with electron microscopic observations that typical desmosomes and tonofilament bundles are absent in lens-forming cells, as opposed to a high density of vimentin filaments. Our observations show that the epithelioid lens-forming cells have normal arrays of (i) microfilament bundles containing proteins of contractile structures; (ii) microtubules; and (iii) vimentin filaments, but differ from most true epithelial cells by the absence of cytokeratins, tonofilaments and typical desmosomes. The question of their relationship to other epithelial tissues is discussed in relation to lens differentiation during embryogenesis. We conclude that the lens-forming cells either represent an example of cell differentiation of non-epithelial cells to epithelioid morphology, or represent a special pathway of epithelial differentiation characterized by the absence of cytokeratin filaments and desmosomes. Thus two classes of tissue with epithelia-like morphology can be distinguished: those epithelia which contain desmosomes and cytokeratin filaments and those epithelioid tissues which do not contain these structures but are rich in vimentin filaments (lens cells, germ epithelium of testis, endothelium).     

Immunogold labelling of actin on sections of freeze-substituted plant cells

Summary We have successfully combined the superior ultrastructural preservation capabilities of rapid freeze fixation and freeze substitution (RF-FS) with immunogold antibody localization techniques to label microfilament (MF) bundles with monoclonal antibody to actin in two different plant tissues:Nicotiana pollen tubes andDrosera tentacles. We have thus verified that the extensive MF bundles seen in these cells after RF-FS are composed of actin, a protein that is difficult to preserve by conventional fixation methods for electron microscopy.