Phenotype modulation in primary cultures of arterial smooth-muscle cells: reorganization of the cytoskeleton and activation of synthetic activities

During primary culture, arterial smooth-muscle cells (SMCs) undergo transition from a contractile to a synthetic phenotype. As a consequence, they lose the ability to contract and, instead, acquire the ability to synthesize DNA, divide and produce extracellular-matrix components. In the present study, we used cytochemical and electron-microscopic methods to study the organization of the cytoskeleton in primary cultures of adult rat and human arterial SMCs. Freshly isolated cells were all in contractile phenotype and stained intensely with NBD-phallacidin, a fluorescent marker for F-actin. Diffuse, positive staining was also obtained using indirect-immunofluorescence microscopy with antibodies against tubulin and vimentin, which are subunit proteins of microtubules and intermediate filaments, respectively. Fine structurally, the cytoplasm of these cells was mainly filled with microfilament bundles coalescing in dense bodies. After a few hours in culture, the SMCs attached to the substrate and started to extend processes in various directions. These stained with antibodies to tubulin and vimentin, but not with NBD-phallacidin. Within 1-3 days of culture, the cells spread out on the substrate and developed a system of actin-containing stress fibre bundles spanning their entire length, as well as a radiating system of microtubules and vimentin filaments, originating in the juxtanuclear region. Fine structurally, these changes corresponded to a marked decrease in the number of microfilaments, an increase in the number of microtubules and intermediate filaments, and the formation of an extensive rough endoplasmic reticulum and a large Golgi complex. The morphological transformation of the cells was accompanied by the coordinated activation of DNA, RNA and protein synthesis.     

Intermediate filaments in smooth muscle from pregnant and non-pregnant human uterus.

The intermediate filament proteins desmin and vimentin from pregnant and non-pregnant uterine muscle and smooth-muscle cells in culture were analysed using SDS/PAGE. The desmin content in uterine muscle increases dramatically during pregnancy, whereas vimentin remains unchanged or changes very little. When muscle cells are kept in culture, a considerable increase in vimentin content is observed as compared with vimentin in freshly isolated non-pregnant uterine tissue. Our results strengthen the view that vimentin and desmin filaments have independent function and turnover, and point to a predominantly structural role for desmin filaments.     

Assembly of amino-terminally deleted desmin in vimentin-free cells

To study the role of the amino-terminal domain of the desmin subunit in intermediate filament (IF) formation, several deletions in the sequence encoding this domain were made. The deleted hamster desmin genes were fused to the RSV promoter. Expression of such constructs in vimentin- free MCF-7 cells as well as in vimentin-containing HeLa cells, resulted in the synthesis of mutant proteins of the expected size. Single- and double-label immunofluorescence assays of transfected cells showed that in the absence of vimentin, desmin subunits missing amino acids 4-13 are still capable of filament formation, although in addition to filaments large numbers of desmin dots are present. Mutant desmin subunits missing larger portions of their amino terminus cannot form filaments on their own. It may be concluded that the amino-terminal region comprising amino acids 7-17 contains residues indispensable for desmin filament formation in vivo. Furthermore it was shown that the endogenous vimentin IF network in HeLa cells masks the effects of mutant desmin on IF assembly. Intact and mutant desmin colocalized completely with endogenous vimentin in HeLa cells. Surprisingly, in these cells endogenous keratin also seemed to colocalize with endogenous vimentin, even if the endogenous vimentin filaments were disturbed after expression of some of the mutant desmin proteins. In MCF-7 cells some overlap between endogenous keratin and intact exogenous desmin filaments was also observed, but mutant desmin proteins did not affect the keratin IF structures. In the absence of vimentin networks (MCF-7 cells), the initiation of desmin filament formation seems to start on the preexisting keratin filaments. However, in the presence of vimentin (HeLa cells) a gradual integration of desmin in the preexisting vimentin filaments apparently takes place.     

Expression of desmin cDNA in PtK2 cells results in assembly of desmin filaments from multiple sites throughout the cytoplasm.

The assembly of intermediate filaments into a cytoplasmic network was studied by microinjecting into the nuclei and cytoplasms of PtK2 cells, plasmids that contained a full length desmin cDNA and an RSV promoter. Immunofluorescence was used to monitor the expression of desmin and its integration into the cells' vimentin intermediate filament network. We found that the expressed desmin co-localized with filaments of vimentin just as it does with fluorescently labelled desmin is microinjected into the cytoplasm of PtK2 cells. As early as two hours after microinjection of the plasmids, small discrete dots and short fragments of desmin could be detected throughout the cytoplasm of the cells. This initial distribution of desmin was superimposed on the filamentous pattern of vimentin in the cells. At 8 hours after microinjection of the plasmids, some of the desmin was present in long filaments that were coincident with vimentin filaments. By 18 hours, most of the desmin was in a filamentous network co-localizing with vimentin. There was no indication that desmin assembly began in the perinuclear region and proceeded toward the cell periphery. In some cells, excessively high levels of desmin were expressed. In these cases, overexpression led to clumping of desmin filaments as well as to an accumulation of diffusely distributed desmin protein in the center of the cells. This effect was apparent at approximately 18 hours after introduction of the plasmid. The native vimentin filaments in such cells were also aggregated around the nucleus, co-localizing with desmin. The microtubule networks in all injected cells appeared normal; microtubules were extended in typical arrays out to the periphery of the cells.     

Confocal analysis of cytoskeletal organisation within isolated chondrocyte sub-populations cultured in agarose

This study reports the cytoskeletal organisation within chondrocytes, isolated from the superficial and deep zones of articular cartilage and seeded into agarose constructs. At day 0, marked organisation of actin microfilaments was not observed in cells from both zones. Partial or clearly organised microtubules and vimentin intermediate filaments cytoskeletal components were present, however, in a proportion of cells. Staining for microtubules and vimentin intermediate filaments was less marked after 1 day in culture however than on initial seeding. For all three cytoskeletal components there was a dramatic increase in organisation between days 3 and 14 and, in general, organisation was greater within deep zone cells. Clear organisation for actin microfilaments was characterised by a cortical network and punctate staining around the periphery of the cell, while microtubules and vimentin intermediate filaments formed an extensive fibrous network. Cytoskeletal organisation within chondrocytes in agarose appears, therefore, to be broadly similar to that described in situ. Variations in the organisation of actin microfilaments between chondrocytes cultured in agarose and in monolayer are consistent with a role in phenotypic modulation. Vimentin intermediate filaments and microtubules form a link between the plasma membrane and the nucleus and may play a role in the mechanotransduction process.     

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Electrophoretic and autoradiographic analyses of the incorporation of ³⁵S-methionine into newly synthesized proteins during myogenesis reveal that presumptive chicken myoblasts synthesize primarily one intermediate filament protein: vimentin. Desmin synthesis is initiated at the onset of fusion. Synthesis rates of both filament subunits increase during the first three days in culture, relative to the total protein synthesis rate. The observed increase in the rate of desmin synthesis (at least 10 fold) is significantly greater than that observed for vimentin, and is responsible for a net increase in the cellular desmin content relative to vimentin. Both filament subunits continue to be synthesized through at least 20 days in culture. Immunofluorescent staining using desmin- and vimentin-specific antisera supports the conclusion that desmin is synthesized only in fusing or multinucleate cells. These results indicate that the synthesis of the two filament subunits is not coordinately regulated during myogenesis. The distributions of desmin and vimentin in multinucleate chicken myotubes are indistinguishable, as determined by double immunofluorescence techniques. In early myotubes, both proteins are found in an intricate network of free cytoplasmic filaments. Later in myogenesis, several days after the appearance of α-actinin-containing Z line striations, both filament proteins become associated with the Z lines of newly assembled myofibrils, with a corresponding decrease in the number of cytoplasmic filaments. This transition corresponds to the time when the a-actinin-containing Z lines become aligned laterally. These data suggest that the two intermediate filament systems, desmin and vimentin, have an important role in the lateral organization and registration of myofibrils and that the synthesis of desmin and assembly of desmin-containing intermediate filaments during myogenesis is directly related to these functions. These results also indicate that the Z disc is assembled in at least two distinct steps during myogenesis.     

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).     

Rho expression and activation in vascular smooth muscle cells

Phenotypic modulation of smooth muscle cells (SMC) involves dramatic changes in expression and organization of contractile and cytoskeletal proteins, but little is known of how this process is regulated. The present study used a cell culture model to investigate the possible involvement of RhoA, a known regulator of the actin cytoskeleton. In rabbit aortic SMC seeded into primary culture at moderate density, Rho activation was high at two functionally distinct time-points, first as cells modulated to the "synthetic" phenotype, and again upon confluence and return to the "contractile" phenotype. Rho expression increased with time, such that maximal expression occurred upon return to the contractile state. Transient transfection of synthetic state cells with constitutively active RhoA (Val14RhoA) caused a reduction in cell size and reorganization of cytoskeletal proteins to resemble that of the contractile phenotype. Actin and myosin filaments were tightly packed and highly organised while vimentin localised to the perinuclear region; focal adhesions were enlarged and concentrated at the cell periphery. Conversely, inhibition of endogenous Rho by C3 exoenzyme resulted in complete loss of contractile filaments without affecting vimentin distribution; focal adhesions were reduced in size and number. Treatment of synthetic state SMC with known regulators of SMC phenotype, heparin and thrombin, caused a modest increase in Rho activation. Long-term confluence and serum deprivation induced cells to return to a more contractile phenotype and this was augmented by heparin and thrombin. The results implicate RhoA for a role in regulating SMC phenotype and further show that activation of Rho by heparin and thrombin correlates with the ability of these factors to promote the contractile phenotype.     

Organization of desmin-containing intermediate filaments during differentiation of mouse decidual cells

Decidualization of the mouse endometrium consists of a redifferentiation of the endometrial stromal fibroblasts. During decidualization these fibroblasts undergo growth, change of shape, multinucleation, and establishment of intercellular junctions. One feature of rodent decidual cells is the accumulation of intermediate filaments. In spite of the fact that fibroblasts normally have vimentin intermediate filaments, they acquire a large amount of desmin intermediate filaments while they undergo decidualization. The light and electron microscope immunocytochemical results of the present work show that during the initial stages of decidual transformation the desmin intermediate filaments accumulate around the nuclei, often forming caps around the nuclear envelope. As the decidual cells grow, the filaments form bundles and nets that radiate from the nuclei toward the cell surface. During the final stages of differentiation, on day 8 of pregnancy, staining of differentiated decidual cells decreases and most filaments accumulate under the cell surface. A role for intermediate filaments is suggested for decidualization of mouse endometrial cells.     

Distribution of laminin,vimentin and desmin in the rat uterus during initial stages of implantation

The aim of this study was to investigate the immunohistochemical distribution of laminin, vimentin and desmin during the implantation period in the rat since ECM remodelling and the expression of intermediate filaments (Ifs) is essential for successful decidualization and implantation. On day 4 of pregnancy, laminin was found in a few endometrial stromal cells (ESC), the basement membrane of the numerous endometrial blood vessels, in endometrial glands and as well as in the uterine epithelium. The localization of vimentin on day 4 of pregnancy was widespread in the ESC. However, desmin immunoreactivity was low in ESC on this day of pregnancy. On day 6 of pregnancy, laminin and vimentin were localized in the decidual area underlying luminal epithelium and around the implanting embryo. Additionally, desmin was found to be present densely in decidual cells of the anti-mesometrial region where implantation takes place. Finally, on day 8 of pregnancy, laminin was present in decidual and parietal endodermal cells, whereas vimentin was immunolocalized in primary and secondary decidual regions in the endometrium. In contrast, desmin was detected in some parts of the secondary decidual zone. In conclusion, these proteins could have crucial roles in decidualization and implantation.     

Intermediate filament protein as a marker of uterine stromal cell decidualization

An increase in intermediate filaments has been reported in rat uterine stromal cells undergoing decidualization in vivo and in vitro. In order to identify biochemical correlates of this morphological change, we have identified (two dimensional gel electrophoresis, Western blots, indirect immunofluorescent staining) the constitutive intermediate filament proteins of stromal cells decidualizing in vivo and isolated stroma decidualizing in vitro as vimentin and desmin. Vimentin is common to all uterine stromal cells but increases, proportional to total cell protein, in decidualized stroma. Barely detectable in nondecidualized stroma, desmin, unlike vimentin, increases during decidualization at a rate greater than the increase in total cell protein. Neither the increase in vimentin or desmin is observed in hormonally sensitized, nondecidual stromal cells. Desmin, because it is selectively expressed in decidualizing stroma, could be considered unique enough to serve as a marker of decidual cell differentiation.     

Visualization of intermediate filaments in living cells using fluorescently labeled desmin

Fluorescently labeled desmin was incorporated into intermediate filaments when microinjected into living tissue culture cells. The desmin, purified from chicken gizzard smooth muscle and labeled with the fluorescent dye iodoacetamido rhodamine, was capable of forming a network of 10-nm filaments in solution. The labeled protein associated specifically with the native vimentin filaments in permeabilized, unfixed interphase and mitotic PtK2 cells. The labeled desmin was microinjected into living, cultured embryonic skeletal myotubes, where it became incorporated in straight fibers aligned along the long axis of the myotubes. Upon exposure to nocodazole, microinjected myotubes exhibited wavy, fluorescent filament bundles around the muscle nuclei. In PtK2 cells, an epithelial cell line, injected desmin formed a filamentous network, which colocalized with the native vimentin intermediate filaments but not with the cytokeratin networks and microtubular arrays. Exposure of the injected cells to nocadazole or acrylamide caused the desmin network to collapse and form a perinuclear cap that was indistinguishable from vimentin caps in the same cells. During mitosis, labeled desmin filaments were excluded from the spindle area, forming a cage around it. The filaments were partitioned into two groups either during anaphase or at the completion of cytokinesis. In the former case, the perispindle desmin filaments appeared to be stretched into two parts by the elongating spindle. In the latter case, a continuous bundle of filaments extended along the length of the spindle and appeared to be pinched in two by the contracting cleavage furrow. In these cells, desmin filaments were present in the midbody where they gradually were removed as the desmin filament network became redistributed throughout the cytoplasm of the spreading daughter cells.     

Transgenic expression of the muscle-specific intermediate filament protein desmin in nonmuscle cells

The coding region of the hamster desmin gene was fused to the 5' flanking sequences of the hamster vimentin gene and introduced into the germ line of mice. The expression of this intermediate filament gene construct (pVDes) was analyzed at the RNA and protein level in transgenic mice as well as in fibroblast cell lines and primary hepatocyte cultures derived from these mice. In all transgenic mice, the pVDes-encoded protein was coexpressed with mouse vimentin in a tissue-specific fashion and was indistinguishable from normal hamster desmin. Culturing of transgenic hepatocytes induced desmin expression indicating that 3.2 kbp of the vimentin gene 5' region regulates both tissue-specific and tissue culture-induced intermediate filament protein expression. Immunohistochemical staining and double-label immunoelectron microscopy of cultured transgenic fibroblasts showed that the pVDes protein assembled into intermediate filaments which colocalized with the mouse vimentin filaments. Endogenous vimentin RNA levels were not influenced by high-level pVDes expression. The coexpression of desmin and vimentin in nonmuscle cells did not result in detectable developmental, morphological, or physiological abnormalities.     

Changes in the composition of cytoskeletal and cytocontractile proteins of rat aortic smooth muscle cells during aging

Cytoskeletal proteins are used as differentiation markers of vascular smooth muscle cells (SMC). To study possible changes in SMC phenotype during aging, cytoskeletal and cytocontractile proteins were quantified in the aortic intima-medias of 4-, 12-, 30-, and 36-month-old rats by one- and two-dimensional gel electrophoresis. The percentages of myosin and desmin in total protein decreased with age, while those of actin and vimentin remained unchanged. Immunohistochemical comparison of the aortas from 4- and 30-month-old rats showed that the reduction of desmin reflected a selective disappearance of desmin in some cells. There was an age-related increase in the proportion of beta-actin at the expense of the alpha-isoform. Our results suggest an age-dependent modulation of the phenotype of vascular SMC towards the synthetic state, which is opposite to that observed during developmental differentiation.     

Antibodies as probes of cellular differentiation and cytoskeletal organization in the mouse blastocyst

Indirect immunofluorescence microscopy has been used to detect cytoskeletal proteins, which allow a distinction between the two cell types present in the mouse blastocyst: i.e. the cells of the inner cell mass (ICM) and the outer trophoblastic cells. Antibodies against three classes of intermediate-sized filaments (cytokeratins, desmin and vimentin), as well as antibodies against actin and tubulin were studied. Antibodies against prekeratin stain the outer trophoblastic cells but not the ICM in agreement with the findings on adult tissues that cytokeratins are a marker for various epithelial cells. Interestingly, vimentin filaments typical of mesenchymal cells as well as of cells growing in culture seem to be absent in both cell types of the blastocyst. Thus, the cytokeratins of the trophoblastic cells seem to be the first intermediate-sized filaments expressed in embryogenesis. Antibodies to tubulin and actin show that microtubules and microfilaments are ubiquitous structures, although microfilaments have a noticeably different organization in the two cell types. In addition, since early embryogenic multipotential cells show close similarities to teratocarcinomic cells, a comparison is made between the cells of the blastocyst, embryonal carcinoma cells (EC cells) and an epithelial endodermal cell line (PYS2 cells) derived from EC cells. EC cells display vimentin filaments whereas PYS2 cells show both vimentin and cytokeratin filaments. The results emphasize the usefulness of antibodies specific for different classes of intermediate filaments in further embryological studies, and suggest that cells of the blastocyst and EC cells differ with respect to vimentin filaments.     

Association of microtubule-associated protein 2 (MAP 2) with microtubules and intermediate filaments in cultured brain cells

The classification of MAP 2 as a microtubule-associated protein is based on its affinity for microtubules in vitro and its filamentous distribution in cultured cells. We sought to determine whether MAP 2 is also able to bind in situ to organelles other than microtubules. For this purpose, primary cultures of rat brain cells were stained for immunofluorescence microscopy with a rabbit anti-MAP 2 antibody prepared in our laboratory, as well as with antibodies to vimentin, an intermediate filament protein, and to tubulin, the major subunit of microtubules. MAP 2 was present on cytoplasmic fibers in neurons and in a subpopulation of the flat cells present in the cultures. Our observations were concentrated on the flat cells because of their suitability for high-resolution immunofluorescence microscopy. Double antibody staining revealed co-localization of MAP 2 with both tubulin and vimentin in the flat cells. Pretreatment of the cultures with vinblastine resulted in the redistribution of MAP 2 into perinuclear cables that contained vimentin. Tubulin paracrystals were not stained by anti-MAP 2. In cells extracted with digitonin, the normal fibrillar distribution of MAP 2 was resistant to several treatments (PIPES buffer plus 10 mM Ca++, phosphate buffer at pH 7 or 9) that induced depolymerization of microtubules, but not intermediate filaments. Staining of the primary brain cells was not observed with preimmune serum nor with immune serum adsorbed prior to use with pure MAP 2. We detected MAP 2 on intermediate filaments not only with anti-MAP 2 serum, but also with affinity purified anti-MAP 2 and with a monoclonal anti-MAP 2 prepared in another laboratory. We conclude from these experiments that material recognized by anti-MAP 2 antibodies associates with both microtubules and intermediate filaments. We propose that one function of MAP 2 is to cross-link the two types of cellular filaments.     

Association of acetylated microtubules, vimentin intermediate filaments, and MAP 2 during early neural differentiation in EC cell culture

Pluripotent P19 embryonal carcinoma cell cultures can be induced to differentiate into neurons and glial cells by the addition of 10(-6) M retinoic acid. During early neural differentiation, a bundle of colchicine-stable, acetylated microtubules is formed. This acetylated microtubule array apparently extends to form neurites during neurogenesis. In this paper, we analyze changes in vimentin and MAP 2 distributions during neural differentiation with respect to the changes in the acetylated microtubule array. During a brief period early in differentiation, indirect immunofluorescence staining shows the colocalization of colchicine-stable acetylated microtubules, vimentin, and MAP 2. Using acrylamide to disrupt the organization of vimentin intermediate filaments and estramustine to disrupt the binding of MAP 2 to microtubules, we show that acetylated microtubules, MAP 2, and vimentin intermediate filaments are arranged in an interdependent cytoskeletal array. We suggest this array may serve to stabilize processes in neural stem cells, before the final decision to differentiate into neurons or glia is made.     

Differential location of different types of intermediate-sized filaments in various tissues of the chicken embryo.

The location of constitutive proteins of different types of intermediate-sized (about 10 mm) filaments (cytokeratin, vimentin, desmin, brain filament protein) was examined in various tissues of 11--20 day chick embryos, using specific antibodies against the isolated proteins and immunofluorescence microscopy on frozen sections and on isolated serous membrane. The tissues studied which contained epithelia were small intestine, gizzard, esophagus, crop, liver, kidney, thymus, mesenteries, and epidermis. The results show that the different intermediate filament proteins, as seen in the same organ, are characteristic of specific lines of differentiation: Cytokeratin filaments are restricted to--and specific for--epithelial cells; vimentin filaments are seen--at this stage of embryogenesis--only in mesenchymal cells, including connective tissue, endothelial and blood cells, and chondrocytes; filaments containing protein(s) related to the subunit protein prepared from gizzard 10 nm filaments (i.e., desmin) are significant only in muscle cells; and intermediate filament protein of brain, most probably neurofilament protein, is present only in nerve cells. We conclude that for most tissues the expression of filaments of cytokeratin, vimentin, desmin, and neurofilament protein is mutually exclusive, and that these protein structurees provide useful markers for histochemical and cytochemical differentiation of cells of epithelial, mesenchymal, myogenic, and neurogenic differentiation.     

Influence of fibric acid derivatives on intermediate filament proteins in myocardiocyte cultures

We analyzed desmin and vimentin accumulation in chick myocardiocyte cultures treated with the fibric acid derivatives bezafibrate, fenofibrate and gemfibrozil. The most noteworthy finding was the 50% decrease in the cytoplasmic desmin fraction in cells treated with gemfibrozil in comparison to control cultures, and the 19% increase in the cytoskeletal fraction in cultures treated with gemfibrozil and with bezafibrate. Vimentin accumulation by cells treated with bezafibrate was similar to that in control cultures, however the cytoskeletal vimentin fraction rose by 26% after treatment with gemfibrozil, and fell 13% after treatment with fenofibrate. No vimentin was found in the cytoplasmic fraction of cell treated with bezafibrate. Given the role of intermediate filaments in heart muscle contraction, fibric acid derivative- induced changes in the cytoplasmic and cytoskeletal concentrations of intermediate filament proteins may be related with the secondary effects of these drugs on heart rate.